Long to try your hand at building a pedal but can't help feeling overwhelmed? Let us enlighten you on the tools, materials, and available resources, as well as teach you how to build a critical, oft-overlooked testing device.
The DIY guitar-pedal world has been exploding over the past few years—so much so that it's likely at least a few of you have dipped a toe in already. I know I did. After using pedals for so many years and becoming pretty much obsessed with them, I felt a burning desire to learn what's going on inside these contraptions. But initially I was pretty intimidated. There is so much to learn! And even though we live in an age when all the information we need is practically at our fingertips, it's sometimes difficult to know how to word things in a search engine to get what we're looking for. Luckily, there's an immense DIY community out there, too—blogs, forums, and general-information reference sites. In my experience, just about everyone in the community is eager to help each other, so it didn't take long for me to feel welcome and encouraged.
Even so, two big things have become glaringly obvious to me during my years of pedal building. First, while there's a ton of information and lots of goodwill on the scene, there isn't really a single place that pulls together both the most important foundational concepts and a comprehensive list of the tools a novice needs to have not just a fun time, but a successful first building experience. No one likes spending a bunch of time and money on parts, tools, and assembly only to have a worthless hunk of junk that doesn't work at the end of it all.
Secondly, very few places mention one of the most important, helpful, and time- and wits-saving tools that a would-be pedal builder can have at their disposal. No matter how experienced you are, no matter what you're building, the simple fact is that if you don't have a circuit-tester box, you're probably losing a lot of time and getting way more frustrated than you need to during a pedal build.
What exactly is a circuit-tester? It's a special, prewired "dummy" pedal you can use over and over again to test any circuit you're working on. In other words, it will function as the vicarious housing for any DIY pedal project you're working on, allowing you to hear it and know that it works before you install the project in a housing with its own jacks, etc. To that end, I put together this brief tutorial for a DIY tester box. Besides being very useful for any future pedal projects you might undertake, the tester-building process itself will be great practice for upcoming pedal builds, too. Once you've mastered this, you'll be ready to move onto building your first pedal, whether it's a kit or a copy of a popular circuit.
Let's start with essential tools, since there are so many options on the market that might seem fine but actually aren't well suited to pedal-building tasks.
Essential Pedal-Building Tools
Soldering iron. You don't need the fanciest one around, but a cheapie can definitely make your projects a lot less fun. An iron of 40 or more watts will get the job done. And while you don't have to get one with a digital readout, it's a heck of a lot easier to use. Otherwise, you'd need to rig up a way to test your iron's temperature to ensure it stays at an appropriate, steady temperature for creating good solder joints. I solder at anywhere from 600 to 750 degrees, and I like the set-it-and-forget-it aspect of digital soldering irons. If the temperature drifts, the readout will reflect that fluctuation and readjust within seconds. I've tried about six different soldering irons, including an expensive Weller digital model. I keep going back to the Hakko FX-888D, but if you're not quite ready to plunk down a hundo on your iron, the Weller WLC100 40-Watt Soldering Station will work just fine, too.
Soldering tips. Soldering stations typically come with one soldering tip, usually a large one that's not very useful for pedal building. There are many sizes to choose from, but I tend to use two sizes mostly: a .8mm conical tip and, much less often, a .8mm chisel tip. In my experience, it is better to purchase original-equipment-manufacturer (OEM) brand soldering tips, as after-market tips often don't last long.
Solder. The type of solder typically used for this type of work has an activated rosin flux core and is composed of approximately 60 percent tin and 40 percent lead, although lead-free options are available. I have tried many kinds—lead-free, silver-bearing, no-clean, you name it. I've found lead-free solder incredibly difficult to work with, though perhaps I will find one that works for me in the future. Some folks like a bit thicker diameter of solder than the Kester .02"-diameter solder that I use. I find anything from .02" to .03" in diameter acceptable for pedal building. (Note: Even if you've been soldering for a while, I also recommend finding out more about it from a source such as ElectronicsAndYou.com. There's also a wonderful tutorial video by trusted electronics outfit Pace, Inc.)
Something to clean your iron. This is something you should be doing quite frequently! A moistened sponge works, while something like the handy Hakko 599B Tip Cleaner helps prevent solder blobs from flying in your face or hair.
Smoke absorber. Solder fumes are highly toxic, so a de-fuming fan/smoke absorber is essential—even if you're working in a well-ventilated room. I use a Hakko FA-400, but I still keep all shop windows open and use a ceiling fan to keep the air circulating out. Placing a soldering station right next to an open window with the de-fumer blowing the fume-y air out is the easiest way I have found to keep solder smoke from lingering.
Pliers. I use three different sets of pliers every time I build: a flat long-nose variety with no teeth, a skinny long-nose with no teeth, and flat long-nose pliers with teeth.
Wire cutters. For snipping wires and component leads. I tend to break wire cutter tips rather often, so I keep a few pairs around. I have a robust pair for cutting thick wires and metal, a pair of Xytronic AX103 Side Cutters for most everyday clipping work, as well as a fancy, sharp pair for more dainty work (like snipping leads off of PCBs).
Wire strippers. For trimming a small piece of each wire's outer coating (or "jacket") to expose the bare wire underneath. I like models like this Hanlong 20-30AWG stripper because they can strip a few different gauges of wire. "Self-adjusting" wire strippers like models from Irwin are also popular with some builders, though I find them a bit clunky to use. Note: When I'm not using wire salvaged from unused electronics, I prefer Teflon-coated wire because its outer jacket won't melt. One disadvantage, however, is that it's slippery as can be and nearly impossible to strip with the previously mentioned strippers. The tiny Jonard ST-550 works wonderfully with Teflon—and any other kind of jacket material.
A drill and drill bit(s). A powered hand drill will work fine, however I like to use a step bit like the Irwin 10231 Unibit self-starting fractional step drill bit so I don't have to change the bit every time I want to drill a different-sized hole. You might also want to pick up a center punch like those from Starrett, as well as a very small bit (1/16" or 1/8") that's made to go through aluminum or metal to drill pilot holes for the step bit.
Rocket Sockets. They're not absolutely necessary, but they make installing jacks and hardware easier, faster, and safer. (Trust me—if you use pliers to tighten hardware, they're almost guaranteed to scratch the finish.) Rocket Sockets come in a set that includes all the sizes you'll need for building pedals.
Circuit-board blanks. Two kinds of circuit-board substrate are most widely used for pedal circuits: stripboard (Veroboard is a common brand) has preprinted, horizontal copper rails, while perforated board (aka "perf board") looks similar but doesn't have copper rails (although some types of perf boards have copper tracing around each of the holes). Parts get directly loaded through the top of the board and are connected to each other on the underside. Note: Because we'll be wiring all our circuit-tester parts together directly (aka "point to point"), you won't need circuit-board material for the direct purposes of this article.
Helping Hands circuit-board holder. This affordable Radio Shack accessory is incredibly useful for holding boards and parts while you solder them.
Digital multimeter. This isn't absolutely necessary for our project, but if you expect to keep building pedals it will definitely end up being the most important tool in your kit. Why? To avoid massive headaches at the end of your build, it's a good idea to get in the habit of testing all components before adding them to the circuit. A multimeter is also useful for checking continuity when you solder any two (or more) points together. Cheaper multimeters have a rotary dial that must be set to certain ranges of values to get an accurate reading. I prefer "auto-ranging" multimeters, which automatically test the exact value of an electrical component simply by putting a probe on each of its "legs." The affordable Vici VC97A works well in my experience.
Semiconductor analyzer. The Peak Atlas DCA55 is one of the most-used tools in our shop. We use it to quickly and accurately measure transistors and diodes.
Screwdrivers. One standard-size flathead and one standard-size Phillips head are a must. I also use small screwdrivers for all sorts of things, including forming leads, pushing wires and components into place in tight spaces, and installing knobs. Radio Shack's RS Pro 6-Piece works just fine.
X-Acto #1 precision knife. I can't tell you how handy and necessary these are in every aspect of my creations!
Scissors. I like Fiskars Softouch Micro-Tip Pruning Snips, but just about any kind will work.
Radio Shack Hot Holder. This silicon block has molded compartments for holding everything from 1/4" jacks to footswitches, RCA and XLR plugs, and even pickup switches while you solder parts onto them. I initially balked at the price, but I have to admit I'm using it often.
Desoldering bulb. Learning to desolder is an invaluable skill, as even the most seasoned pedal builders make soldering mistakes, and circuit-board pads and traces don't typically stand up to a lot of reheating while you try to do the job with just your soldering iron. A great way to practice is by desoldering components off PCBs from old or broken electronics. This is one of my favorite things to do, because you get comfortable with the process while saving a precious transistor or two from landfills. (There are other ways to desolder—some folks like to use a pump or solder wick. But I find the bulb to be the easiest, cleanest method, because you can apply different amounts of pressure to desolder more delicately.)
Parts Needed for Our Circuit-Tester Project
Hookup wire. 22- and 24-gauge stranded, pre-bond hookup wire is most common in pedal building, as anything thicker than 22 won't fit some hardware and some circuit-board holes, while anything thinner than 24 won't be robust enough. Jackets can be made of a few different materials— cloth-covered, polytetrafluoroethylene (Teflon)-coated, or the polyvinyl chloride (PVC) type most builders use. You can even get your preferred wire type in pre-cut, pre-"tinned" sets. However, knowing how to strip and tin wires (condition their tips for proper conduction—we'll talk more about this later) is a valuable skill, so I suggest using raw wire like the 24-gauge options available from LoveMySwitches.com.
DIY TIP: Although many pro pedal builders use a single color of wiring for their circuits, it's a good idea for new builders to purchase red, black, green, and blue wire, since, when you go a-hunting for layouts to build, you'll find that many use this color-coding scheme to denote positive, ground, input, and output wires, respectively—just as we have in our circuit-tester project.
Testing leads. Most pedal circuits have four wires coming off of the circuit boards: input (the green lines in our diagrams), output (blue lines), positive (red +9V lines), and ground (black). That means we'll need four testing leads. Because our circuit-testing box will be used over and over again, we should invest in quality, durable leads. I've found Mueller BU-2031-A-12-0 leads to be robust. (If you prefer longer leads, Velleman sets will work as well—but be sure to buy two packages, since each only comes with three.) The alligator-clip end of each lead hooks onto the input, output, positive, or ground wires of the circuit board we are testing, and the "banana-plug" end of each lead plugs into the corresponding banana post (see next entry for more) on the tester pedal.
You can also make your own leads to the exact lengths that are ideal for your workstation. If you go that route, Keystone Electronics 5046 alligator clips are a nice choice. Mueller even has a helpful video showing three different ways to attach an alligator clip to a wire. Meanwhile, AudioTrendsTV has a helpful video showing how to solder a banana plug. (Solder-less screw-on plugs are available, but in my experience the soldered variety are much more durable. If you buy the screw-on type, I recommend soldering the wire in for extra strength.)
You'll also need four banana plugs, and Mueller tapered-handle models are a good option. "Banana plugs" are single-wire electrical connectors used for joining wires to equipment, and the awesome thing about them is that the leads are removable, so you have a ton of options as far as tester leads go. Just be sure to buy the ones with an alligator clip on one end and a 4 mm male banana post on the other.
Banana posts. These are the jacks that the detachable test lead cables with alligator clip ends will plug into when the tester pedal is finished. They are also sometimes referred to as "binding posts" or "terminal binding posts," and you'll need four of these, too.
A metal enclosure. Aluminum enclosures are the most widely used for guitar pedals. For our project, I used an aluminum 1590BB-size enclosure I already had from a previous project. LoopholePedals.com is one of many places that offers drilling services for those who don't have the tools to do so themselves.
Jacks. Our test box has two 1/4" female audio jacks, as well as one 2.1 mm barrel power jack. I use Switchcraft #11 monoand #12B stereo jacks, and Lumberg or Mouser DC jacks.
9V batteries. Batteries are terrible for the environment, but we sometimes need them for circuit testing. I always plug into a circuit powered by just the battery at first. Once it powers on properly, I switch to a 9V DC center-negative power supply for further testing. Rechargeable 9V batteries help ease environmental impact and are easy to charge via USB cable. They don't seem to hold a full 9V charge, but since I only use them for the initial test, the 8.6V I've measured from their leads is good enough.
• 9V battery clip connector (center-negative) power-supply cable. To connect the rechargeable battery to the tester pedal's power jack without having to remove the back of the enclosure. (Don't worry—if you prefer a regular 9V connector, I'm including the wiring scheme for that, too.)
9V, center-negative regulated power supply. Clean power is crucial for a pedal, but especially so when you're testing it. I use the Electro-Harmonix US96DC-200BI, because the power seems to be clean and less noisy than others (I've tried more than a dozen brands).
A latching 3PDT (triple-pole, double-throw) switch. It can be either a footswitch or a toggle.
Note: Speaking of switches, it's a good idea to research how they work if you haven't already done so. Understanding how the internal mechanisms connect and how the connections change as the switch is engaged makes the whole off-board-wiring experience much less daunting. BeavisAudio.com has some very useful information on the subject, and DIY Guitar Pedals has an informative video, too.
Bypass LED (light-emitting diode) and LED holder. Pick any color you like. 5 mm and 3 mm models seem to be most popular for pedal building.
1kΩ 1/4-watt resistor. LEDs are quite robust, but they need a resistor attached as a current limiter so they don't blow. You can use a 2.2k or 4.7k resistor too. The higher the resistance, the dimmer the light will be.
The Pedal Builder’s Best Friend: How to Build a Circuit Tester
Okay, I think I've hyped this killer tool enough. Unless you need to take a sec to go online and consult our Soldering 101: A Step-by-Step Guide, let's build this thing! Here's a wiring diagram.
1. Drill the housing. Before we can start wiring, the enclosure needs holes drilled out to accommodate the input, output, and power jacks, as well as the LED and bypass (on/off) switch. If your enclosure didn't come with predrilled holes, you can drill for the jacks on the housing's top or sides, whichever you prefer. I prefer power and audio jacks on top, with the power jack in the center and the input and output jacks opposite each other whenever possible.
We also need to drill four holes for the banana posts that will be connected internally. As mentioned earlier, every circuit you build will have input (green diagram lines), output (blue), positive (red), and ground (black) wires that need to be connected to your tester pedal. Note: The enclosure I'm using already had four holes on top, so my layout reflects this. You might choose to put the banana posts on the side(s), top, or someplace else. That's the beauty of DIY!
I have a mantra: Measure three times, drill once. You can use a Sharpie or other marker to mark the spots you want to drill. Hit each mark with the center-punch tool, then drill pilot holes. Once pilot holes are drilled, you're ready to install your step bit in the drill. (Reminder: The step bit is marked on its side with size values so you know where to stop drilling for the desired hole size.)
PRO TIPS: Some DIY sites have drill guides you can download and print out to make the process easier, but it's still good to learn how to do it manually. Also, Barry Steindel from GuitarPCB.com has a great video tutorial on how to drill pedal enclosures with a hand drill, and DIY Guitar Pedals has one for those who prefer a drill press.
IMPORTANT: Most component and hardware manufacturers publish data sheets listing characteristics and specifications—including physical measurements—for their products. It's a good idea to consult the data sheet for each of your components prior to drilling so that you know how many steps of your step drill bit (or which sizes of standard drill bits) to use.
2. Prepare the switch. To start with, let's connect a couple of "jumpers" on the underside of our 3PDT switch so it functions as a "true bypass" switch (which provides the most transparent signal for circuit testing). This can be done a few different ways, but my preferred method is to add a wire between lugs 1 and 8, as well as lugs 6, 7, and 9. (As you see in the image below, some builders use a 0Ω resistor rather than a bare wire for the jumper between lugs 6, 7, and 9. It's perfectly fine to use a simple wire for this, which is why I didn't include a second resistor in the list of necessary parts for this build.) For now, only apply solder to the three bottom lugs, since the two other lugs (1 and 6) also need to accommodate the wires we'll add in later.
Note: Although you can use regular hookup wire, I use snipped-off leg pieces from resistors or other components for these jumpers.
3. Prepare the LED wiring "harness." First, we're going to trim the LED's ground (cathode) lead, which is the shorter leg. Then we'll "tin" the trimmed end by touching the soldering-iron tip to it, applying a tiny dab of solder, and then sliding the iron tip back and forth along the ground lead for a brief moment until the solder melts and the entire surface of the leg appears shiny. Why? Tinning limits corrosion of the metal leads and helps components fuse together better at solder joints. The LearnElectronics channel has a useful tinning demo video.
Next, cut all but a 1/4" off the 1kΩ resistor's legs, then tin the short end. Put the LED's body into one of the "hands" of the Helping Hands tool, with the legs facing inward, then put the long lead of the resistor in the other "hand," with the snipped, tinned leg facing in. Push the "hands" together until the two short, tinned leads of each component overlap. Touch the soldering-iron tip to the junction for a brief moment, add a dab of solder, and remove the iron's tip once the solder has pooled and settled in, nice and shiny. A shiny solder joint is generally a solid solder joint.
The leftover leg on the 1kΩ resistor is sometimes long enough to be soldered directly to the footswitch, as is the case here. But if your LED hole is further away than ours, you'll need to add a wire. To do this, trim the resistor's other leg to 1/4" and tin it. Next, strip and tin a piece of black hookup wire long enough to reach from the 3PDT switch to the LED hole. Now snip the LED's longer leg (the positive or "anode" lead), again to a 1/4", and tin it. Cut another wire long enough to reach from your power jack to the LED hole, then strip and tin the ends. Load the stripped, tinned wire into the other Helping Hands holder and push the "hands" together until the end of the wire overlaps the LED's anode. Solder them together so that the solder has pooled and settled, nice and shiny, as before.
Although it's not crucial, you can encase these two solder points in 1/8" shrink tubing for extra stability, neatness, and to help keep the joints from shorting out against each other or the enclosure (don't use electrical tape instead—you'll regret it!). The YouTube channel MrJustDIY has a helpful video on how to do so. The most important thing is to make sure your solder joint is good before you cover it. I recommend testing for continuity with a multimeter before adding the shrink stuff.
4. Install the enclosure's hardware. With our footswitch and LED harness ready to go, we're set to use those Rocket Sockets (or other appropriately sized socket wrenches) to attach the footswitch and the input, output, and power jacks.
As for the banana posts, they have a hollow, threaded column with an insert at the top that accepts a banana plug. IMPORTANT: You don't want that metal post touching the metal enclosure at all. Thankfully, banana posts come with plastic insulators that go around the post, ensuring that they don't short-out the circuit. Install the banana post from the top, as shown below.
Next, put the plastic insulator cylinder over the post, followed by the little tab thing, then the nut. Tighten it snugly, but be careful not to crack the plastic insulator by over-tightening.
Note: If you're wondering why my LED isn't installed in a holder/bezel, it's because my recycled enclosure already had an LED glued in. It's much cleaner and sturdier to use a holder or bezel, however. If you aren't using shrink tubing around the joints, it's imperative that none of the bare leads touch the bezel (if it's metal) or the enclosure. We don't want it to short out—or worse, to blow! When you install your LED, make sure the positive and ground wires are properly oriented before you push the LED into the holder. Point the positive wire toward the power jack, and gently bend the ground-plus-resistor lead toward the bypass switch.
5. Wire and solder the circuit. Measure the distance to and from each of the points that need to be connected, as per the wiring diagram—and, ideally, in the same colors. Be sure to add a couple extra millimeters on each wire, as it's really annoying to get in the building groove only to realize a wire is too short! Next, use your wire strippers to strip 1/4" of the plastic jacket off the ends of each wire. As you tin each wire end, keep in mind that PVC jacketing melts very easily, so don't apply heat too long or you'll end up with a mess. The tinned wire ends should look shiny all the way around, like they're encased in chrome.
TECH TALK: Let's discuss 1/4" jack anatomy for a second. We are using two types—our output jack is mono and has two tabs, while our input jack is stereo and has three tabs. Turn the input jack sideways, and you'll see three protective wafer layers separating three metal terminals on the jack. These are commonly referred to as the "tip" and "ring." The ring is above the second wafer. The tip is the terminal above the first wafer, just above the base of the jack itself. The ground tab, or sleeve, is connected to the center part of the jack at the base, floating above all three wafers, and does not have a protective wafer on top. The output jack will only have two protective wafers separating the two metal conductors (the ground and tip tabs). If you decide not to add the battery snap internally, you could use two mono Switchcraft jacks as you would not need the additional ring connection used for turning the battery on and off.
Okay, let's insert and solder all the ground wires first. I always use black wire to avoid confusion and match the diagram. Again, make sure each solder joint is shiny before you move to the next one. Also, be sure none of the wires are too taut, or they're likely to eventually come loose.
Next, I like to insert and solder the red, positive-connection wires. This is easier than ground wiring, because it only connects in two spots and one wire is already attached to the LED's positive leg. Note: Although the diagram looks like only one wire is attached to the power jack, a separate red wire will go from both the LED and the positive banana post to the power jack's sleeve pin (see photo). Both wires should fit there fine, but don't solder that joint until both wire tips are gently squeezed into the hole.
If you want to install a battery snap, do that now. Strip and tin the ends. Note: Soldering the red wire to the power jack's one remaining empty tab prevents the battery from losing juice—but only if you remember to unplug your 1/4"instrument cable from the input when you're not using the box. Plugging into the input connects the battery. Unplugging disconnects it.
Now let's install our input (green) wires. One goes from the tip of the input jack to lug 2 (middle lug in the leftmost column) of our 3PDT switch. The other green wire goes from the input banana post's tab to lug 1 (top left) on the switch, along with one end of the jumper.
To connect output (blue) wires, route one from the tip of the output jack to lug 8 (middle of rightmost column) on the switch. The second blue wire goes from the output banana post to lug 7 (top right) on the 3PDT switch.
Lastly, connect the LED's ground leg to lug 4 (top row, middle) on the footswitch. Remember, my example looks a little different and your ground will be the black wire coming off the LED.
6. Test the circuit with a multimeter. Set your meter to "continuity" mode (consult its manual if you're not sure how to do so), touch one of its probes to a solder point in our circuit tester, then touch the other probe to the solder point on the other end of that particular connection. For example, touch one probe to the solder point located on the input-jack tip, and touch the other probe to lug 2 (middle lug in the leftmost column) of our 3PDT switch. Your meter should beep or light up if you have a solid connection. Once you've tested and found continuity in all our circuit tester's connections, you'll know it's ready to start testing guitar-pedal guts.
Using your new circuit tester is really easy. First, make sure it's got power from a 9V battery or an adapter, then simply plug your guitar into the tester's input jack, and your amp into its output. Then attach each of the circuit-tester's four leads (input, output, ground, and positive) to the corresponding wires on the circuit board you're building or testing. In other words, connect the alligator clip from your new circuit-tester's input lead to your project pedal's input wire, connect the alligator clip from the tester's output lead to the output wire on your project pedal, and so on for the positive and ground connections, as well. That's it! Engaging the bypass switch will connect the circuit. Bypassing will yield a clean guitar signal.
Now you have a simple, easy way to test all the wonderful DIY effects you'll be building. Congratulations! Hopefully, this article has shined a little light on the processes involved with learning to wire a pedal. Moreover, I hope you had as much fun building it as I did! In fact, I'd love it if you'd share your tester-pedal shots with Loe Sounds (@loesounds) on Instagram Stories.
I would be remiss if I didn't acknowledge Steve Daniels and the crew at Small Bear Electronics for their dedication to providing education and reliable supplies to the DIY pedal community for 22 years. At publication time, Small Bear had announced it would soon be closing its doors. Pedal builders everywhere will miss them dearly, and we can only hope someone comes along to carry the torch and fill the big void Small Bear will leave.
DIY Pedal Sites You Should Check Out
- The DIYStompboxes.com forum is my go-to. It's where I met invaluable mentors like Pink Jimi Photon (of PJP Effects), and Dino Tsiptsis and Phil Moulder, whose Dead End FX site has intermediate to advanced projects and PCBs, including some pretty rare stompbox gems.
- The Effects Layouts blog features some of the tidiest PCBs and layouts for perf boards based on popular guitar-pedal schematics.
- The Tagboard Effects blog has Vero-type stripboard layouts for popular pedal schematics, as well as a helpful forum.
- Madbean Pedals hosts a forum with lots of really nice, helpful folks. They've also got downloadable PCB layouts, sell quality PCBs, and some of the most well-documented projects out there, from beginner to advanced level.
- Beavis Audio Research has a whole bunch of great information, including well-laid-out, easy-to-read diagrams.
- R.G. Keen's Geofex. Keen is practically the godfather of DIY guitar effects. Most of us couldn't be doing what we are doing without what we have learned from this invaluable site!
- RunOffGroove.com is an old-school site with great, bare-basics schematics and articles.
- ElectroSmash.com is a treasure trove of projects, schematics, component information, and detailed breakdowns of popular pedal circuits.
- MusicFromOuterSpace.com features mostly DIY synth stuff, but I learned so much from their articles. Ray Wilson's contributions to the DIY community are too many to count.
- Experimentalists Anonymous allows you to make your own layouts from dozens of schematics.
- DIY Layout Creator offers freeware for designing layouts and is great for learning.
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The range of clean, dirty, and complex tones available from this high-quality, carefully crafted Dumble modeler make it a formidable studio and performance device.
Fantastic variation in many delicious sounds makes it a bargain. High-quality. Easy to use and customize. Killer studio path to lively, responsive guitar sounds.
Price may be hard for some to swallow if they don’t leverage the whole of its potential.
$399
UAFX Enigmatic ’82 Overdrive Special
uaudio.com
I’ve never played a realDumble. I’d venture most of us haven’t. But given my experiences with James Santiago’s UAFX modeling pedals, most recently theUAFX Lion, I plugged in the new Dumble-inspired UAFX Enigmatic confident I’d taste at least the essence of that very rare elixir. You could argue there is no definitive Dumble sound. Each was customized to some extent for the customer, and they are renowned nearly as much for dynamic responsiveness and flexibility as their singing, complex, clean-to-dirty palettes.
The Enigmatic nails the flexibility, for sure. To my ears, its tone foundation lives somewhere on a sliver of Venn diagram where a black-panel Fender and a 50-watt Hiwatt intersect. It’s alive, dimensional, snappy, sparkly, massive, and, at the right EQ settings, hot and excitable. But the Enigmatic’s powerful EQ and gain controls, multiple virtual cab and mic pairings, rock, jazz, and custom voices, plus additional deep, bright, and presence controls enable you to travel many leagues from that fundamental tone. The customization work you can do in the app enables significant changes in the Enigmatic’s tone profile and responsiveness, too. All these observations are made tracking the Enigmatic straight to a DAW—making the breadth of its personality even more impressive. But the Enigmatic sounds every bit as lively at the front end of an amp, and black-panel Fenders are a primo pairing for its saturation and sparkly attributes. The Enigmatic is nearly $400, which is an investment. But considering the ground I covered in just a few days with it, and the quality and variety of sounds I could conjure with the unit just sitting on my desk, the performance-to-price ratio struck me as very favorable indeed.
This simple passive mod will boost your guitar’s sweet-spot tones.
Hello and welcome back to Mod Garage. In this column, we’ll be taking a closer look at the “mid boost and scoop mod” for electric guitars from longtime California-based tech Dan Torres, whose Torres Engineering seems to be closed, at least on the internet. This mod is in the same family with the Gibson Varitone, Bill Lawrence’s Q-Filter, the Gresco Tone Qube (said to be used by SRV), John “Dawk” Stillwells’ MTC (used by Ritchie Blackmore), the Yamaha Focus Switch, and the Epiphone Tone Expressor, as well as many others. So, while it’s just one of the many variations of tone-shaping mods, I chose the Torres because this one sounds best to me, which simply has to do with the part values he chose.
Don’t let the name fool you, this is a purely passive device—nothing is going to be boosted. In general, you can’t increase anything with passive electronics that isn’t already there. Period. But you can reshape the tone by deemphasizing certain frequencies and making others more prominent (so … “boost” in guitar marketing language). Removing highs makes lows more apparent, and vice versa. In addition, the use of inductors (which create the magnetic field in a guitar circuit) and capacitors will create resonant peaks and valleys (bandpasses and notches), further coloring the overall tone. This type of bandpass filter only allows certain frequencies to pass through, while others are blocked, and it all works at unity gain.
“You can’t increase anything with passive electronics that isn’t already there … but you can reshape the tone by deemphasizing certain frequencies and making others more prominent.”
All the systems I mentioned above are doing more or less the same thing, using different approaches and slightly different component values. They are all meant to be updated tone controls. Our common tone circuit is usually a variable low-pass filter (aka treble-cut filter), which only allows the low frequencies to pass through, while the high frequencies get sent to ground via the tone cap. Most of these systems are LCR networks, which means that there is not only a capacitor (C), like on our standard tone controls, but also an inductor (L) and a resistor (R).
In general, all these systems are meant to control the midrange in order to scoop the mids, creating a mid-cut. This can be a cool sounding option, e.g. on a Strat for that mid-scooped neck and middle tone.
Dan Torres offered his “midrange kit” via an internet shop that is no longer online, same with his business website. The Torres design is a typical LCR network and looks like the illustration at the top of this column.
Dan’s design uses a 500k linear pot, a 1.5H inductor (L) with a 0.039 µF (39nF) cap (C), and a 220k resistor (R) in parallel. Let’s break down the parts piece by piece:
Any 500k linear pot will do the trick, in one of the rare scenarios where a linear pot works better in a passive guitar system than an audio pot.
(C) 0.039µF cap: This is kind of an odd value. Keeping production tolerances of up to 20 percent in mind, any value that is close will do, so you can use any small cap you want for this. I would prefer a small metallized film cap, and any voltage rating will do. If you want to stay as close as possible to the original design, use any 0.039 µF low-tolerance film cap.
(L) 1.5H inductor: The original design uses a Xicon 42TL021 inductor, which is easy to find and fairly priced. This one is also used in the Bill Lawrence Q-Filter design, the Gibson standard Varitone, and many other systems like this. It’s very small, so it will fit in virtually every electronic compartment of a guitar. It has a frequency range of 300 Hz up to 3.4 kHz, with a primary impedance of 4k ohms (that’s the one we want to use) and a secondary impedance of 600 ohms. Snip off the three secondary leads and the center tap of the primary side and use the two remaining outer primary leads; the primary side is marked with a “P.” On the pic, you can see the two leads you need marked in red, all other leads can be snipped off. You can connect the two remaining leads to the pot either way; it doesn’t matter which of them is going to ground when using it this way.
Drawing courtesy of singlecoil.com
(R) 220k: use a small axial metal film resistor (0.25 W), which is easy to find and is the quasi-standard.
Other designs use slightly different part values—the Bill Lawrence Q-filter has a 1.8H L, 0.02 µF C and 8k R, while the old RA Gresco Tone Qube from the ’80s has a 1.5H L, 0.0033 µF C, and a 180k R, so this is a wide field for experimentation to tweak it for your personal tone.
This mid-cut system can be put into any electric guitar not only as a master tone, but also together with a regular tone control or something like the Fender Greasebucket, or it can be assigned only to a certain pickup. It can be a great way to enhance your sonic palette, so give it a try.
That’s it! Next month, we’ll take a deeper look into how to fight feedback on a Telecaster. It’s a common issue, so stay tuned!
Until then ... keep on modding!
The two-in-one “sonic refractor” takes tremolo and wavefolding to radical new depths.
Pros: Huge range of usable sounds. Delicious distortion tones. Broadens your conception of what guitar can be.
Build quirks will turn some users off.
$279
Cosmodio Gravity Well
cosmod.io
Know what a wavefolder does to your guitar signal? If you don’t, that’s okay. I didn’t either until I started messing around with the all-analog Cosmodio Instruments Gravity Well. It’s a dual-effect pedal with a tremolo and wavefolder, the latter more widely used in synthesis that , at a certain threshold, shifts or inverts the direction the wave is traveling—in essence, folding it upon itself. Used together here, they make up what Cosmodio calls a sonic refractor.
Two Plus One
Gravity Well’s design and control set make it a charm to use. Two footswitches engage tremolo and wavefolder independently, and one of three toggle switches swaps the order of the effects. The two 3-way switches toggle different tone and voice options, from darker and thicker to brighter and more aggressive. (Mixing and matching with these two toggles yields great results.)
The wavefolder, which has an all-analog signal path bit a digitally controlled LFO, is controlled by knobs for both gain and volume, which provide enormous dynamic range. The LFO tremolo gets three knobs: speed, depth, and waveform. The first two are self-explanatory, but the latter offers switching between eight different tremolo waveforms. You’ll find standard sawtooth, triangle, square, and sine waves, but Cosmodio also included some wacko shapes: asymmetric swoop, ramp, sample and hold, and random. These weirder forms force truly weird relationships with the pedal, forcing your playing into increasingly unpredictable and bizarre territories.
This is all housed in a trippy, beautifully decorated Hammond 1590BB-sized enclosure, with in/out, expression pedal, and power jacks. I had concerns about the durability of the expression jack because it’s not sealed to its opening with an outer nut and washer, making it feel more susceptible to damage if a cable gets stepped on or jostled near the connection, as well as from moisture. After a look at the interior, though, the build seems sturdy as any I’ve seen.
Splatterhouse Audio
Cosmodio’s claim that the refractor is a “first-of-its-kind” modulation effect is pretty grand, but they have a point in that the wavefolder is rare-ish in the guitar domain and pairing it with tremolo creates some pretty foreign sounds. Barton McGuire, the Massachusetts-based builder behind Cosmodio, released a few videos that demonstrate, visually, how a wavefolder impacts your guitar’s signal—I highly suggest checking them out to understand some of the principles behind the effect (and to see an ’80s Muppet Babies-branded keyboard in action.)
By folding a waveform back on itself, rather than clipping it as a conventional distortion would, the wavefolder section produces colliding, reflecting overtones and harmonics. The resulting distortion is unique: It can sound lo-fi and broken in the low- to mid-gain range, or synthy and extraterrestrial when the gain is dimed. Add in the tremolo, and you’ve got a lot of sonic variables to play with.
Used independently, the tremolo effect is great, but the wavefolder is where the real fun is. With the gain at 12 o’clock, it mimics a vintage 1x10 tube amp cranked to the breaking point by a splatty germanium OD. A soft touch cleans up the signal really nicely, while maintaining the weirdness the wavefolder imparts to its signal. With forceful pick strokes at high gain, it functions like a unique fuzz-distortion hybrid with bizarre alien artifacts punching through the synthy goop.
One forum commenter suggested that the Gravity Well effect is often in charge as much the guitar itself, and that’s spot on at the pedal's extremes. Whatever you expect from your usual playing techniques tends to go out the window —generating instead crumbling, sputtering bursts of blubbering sound. Learning to respond to the pedal in these environments can redefine the guitar as an instrument, and that’s a big part of Gravity Well’s magic.
The Verdict
Gravity Well is the most fun I’ve had with a modulation pedal in a while. It strikes a brilliant balance between adventurous and useful, with a broad range of LFO modulations and a totally excellent oddball distortion. The combination of the two effects yields some of the coolest sounds I’ve heard from an electric guitar, and at $279, it’s a very reasonably priced journey to deeply inspiring corners you probably never expected your 6-string (or bass, or drums, or Muppet Babies Casio EP-10) to lead you to.
Kemper and Zilla announce the immediate availability of Zilla 2x12“ guitar cabs loaded with the acclaimed Kemper Kone speaker.
Zilla offers a variety of customization to the customers. On the dedicated Website, customers can choose material, color/tolex, size, and much more.
The sensation and joy of playing a guitar cabinet
Sometimes, when there’s no PA, there’s just a drumkit and a bass amp. When the creative juices flow and the riffs have to bounce back off the wall - that’s the moment when you long for a powerful guitar cabinet.
A guitar cabinet that provides „that“ well-known feel and gives you that kick-in-the-back experience. Because guitar cabinets can move some serious air. But these days cabinets also have to be comprehensive and modern in terms of being capable of delivering the dynamic and tonal nuances of the KEMPER PROFILER. So here it is: The ZILLA 2 x 12“ upright slant KONE cabinet.
These cabinets are designed in cooperation with the KEMPER sound designers and the great people from Zilla. Beauty is created out of decades of experience in building the finest guitar cabinets for the biggest guitar masters in the UK and the world over, combined with the digital guitar tone wizardry from the KEMPER labs. Loaded with the exquisit Kemper Kone speakers.
Now Kemper and Zilla bring this beautiful and powerful dream team for playing, rehearsing, and performing to the guitar players!
ABOUT THE KEMPER KONE SPEAKERS
The Kemper Kone is a 12“ full range speaker which is exclusively designed by Celestion for KEMPER. By simply activating the PROFILER’s well-known Monitor CabOff function the KEMPER Kone is switched from full-range mode to the Speaker Imprint Mode, which then exactly mimics one of 19 classic guitar speakers.
Since the intelligence of the speaker lies in the DSP of the PROFILER, you will be able to switch individual speaker imprints along with your favorite rigs, without needing to do extensive editing.
The Zilla KEMPER KONE loaded 2x12“ cabinets can be custom designed and ordered for an EU price of £675,- UK price of £775,- and US price of £800,- - all including shipping (excluding taxes outside of the UK).
For more information, please visit kemper-amps.com or zillacabs.com.