ca·pac·i·tor
/kəˈpasədər/
- Smd Capacitor Code Chart
- Ceramic Capacitor Code Chart
- Smd Capacitor Code Chart Pdf
- Capacitor Code Chart Pdf
- Ceramic Capacitor Code Chart
- Capacitor Code Chart
noun
a device used to store an electric charge, consisting of one or more pairs of conductors separated by an insulator.
Ceramic disc capacitor code / label will normally consist of three numbers followed by a letter. They are very easy to decode to find the value. The first two significant digits represent the first two digits of the actual value, which is 47. The third digit is the multiplier, which is ×1000. The letter J signifies the tolerance of ±5%. Tantalum Capacitor Color Codes; Charts Color Color 1st Figure 2nd Figure Multiplier Voltage: Black 0 1 10: Brown 1 1 10 Red 2 2 100 Orange 3 3 Parallel Capacitance Math: C T = C 1 + C 2 + C 3 Series Capacitance Math: 1/C T = 1/C 1 + 1/C 2 + 1/C 3.
If you found the definition above to be completely inadequate in describing how a capacitor affects your tone, then this article is definitely for you. For anyone just taking in an interest in the electrical components and circuits in their guitar, the ability to truly understand how they work can become very abstract – usually because we tend to try to visualize everything, which is pretty hard to do when it comes to sound and electricity. When you think about a sound after it’s been converted to an electric signal[transduce], what do you see in your mind’s eye? I’m willing to bet that it’s something like this:
- Codes for date of manufacture (to IEC ) Codeforyear Codeformonth Year Code letter Year Code letter Month Code numeral Month Code numeral/letter 2012 C 2018 K January 1 July 7 2013 D 2019 L February 2 August 8 2014 E 2020 M March 3 September 9 2015 F 2021 N April 4 October O 2016 H 2022 P May 5 November N 2017 J 2023 R June 6 December.
- Capacitor Code Chart Pdf Free Capacitor Code Information This table is designed to provide the value of alphanumeric coded ceramic, mylar and mica capacitors in general. They come in many sizes, shapes, values and ratings; many different manufacturers worldwide produce them and not all play by the same rules.
- Sprague “Bumblebee” Capacitor Color Code Chart Tolerance # of Zeros 2nd Figure 1st Figure Voltage Rating in 100’s of Volts 1st Figure Outside Foil Lead 2nd Figure Capacitor Value in MMFD Example: 0.0047 mF 1 Yellow = 4 1600V DC 2 Violet = 7 +/- 20% 3 Red = 00 4 Black = +/- 20% 5 Brown =1 6 Blue = 6 4700 MMFD 1600 V.
You pluck an open E, your pickup’s magnetic field is disrupted and the vibration of the string is inducted by the magnetic coils and the frequencies travel through a copper wire (or silver, if you’re fancy) – so far, you can see everything happening as we go along, but there’s a capacitor in the circuit coming up fast. The frequencies pass through the solder joint, up the little leg into the component. And…something happens in there…
What we know for sure is that the sound is different when it comes out through the output at the end of the line, but how is the tone cap actually affecting the frequencies?
Here, according to definition, our frequencies sit for a brief moment before coming out the other side. Not exactly, let’s forget the definition entirely – it’s a very simple, broad definition that doesn’t really have specific consideration for audio applications. Take a look at your capacitor if you have your circuit handy, or just look at the images below for a moment:
( Ground Wires | Hot Wires | Tone-Cap Wires )
I’ve marked the capacitor wires in blue and given a top and bottom view of the wiring setup – it’s a fairly standard setup, and even though yours may appear a bit different, the capacitor & tone pot are likely the same: one end soldered to the pot’s arm and the second leg is soldered to the bottom of the pot (or somewhere else in the ground circuit). Why doesn’t the whole frequency get grounded off then? Let’s look at the circuit diagram now:
The capacitor is selectively drawing out the higher frequencies and leaving the lower frequencies untouched to carry along down the line. Note that the bass frequencies are ignoring the law of electricity taking the path of least resistance (to the ground). This is where things get slightly complicated: capacitors are actually meant to divert lower frequencies, which is the opposite of what we actually see happening in the diagram – and of what we know happens when you roll your tone knob around.
All of the frequencies are originally attracted to the path of least resistance, but since the capacitor is holding on to the bass frequencies, they actually pass back into the hot circuit (through the same leg they came in) while the high frequencies are allowed to escape out the ground. Stick a potentiometer just in front of the capacitor in the circuit and turn it up – you are increasing the range of higher frequencies allowed to escape through to the ground. That’s the gist of it! And if we return to the definition about electricity being stored and released, we can picture this happening in the correct sequence with perfect clarity (I hope).
If not, then maybe it’d be helpful to think of it as a resistor that only resists lower frequency ranges. The highs and the lows enter the resistor attempting to pass through to the ground circuit – the lows get stopped in the cap and turned away while the highs just skim right past to ground. A higher capacitance value gives a darker tone because a wider range of high frequencies is allowed to escape.
Why does putting a potentiometer right in front of the capacitor only affect the tone instead of the volume? Good question, me. That’s most definitely a question for a potentiometer article though, because it’s going to require a complete breakdown of the pot mechanism as well.
Electricity is confusing sometimes, and it took me some time to go out of the way to research all of this stuff – before that, I would just work off of diagrams knowing A + B = C without any deeper understanding. After I took the time to learn about what I was putting together and how these components are all working with each other (or against in most cases), I had a flood of new questions and theories to find answers for and felt like I was ready to start taking on some more ambitious modifications.
Capacitor Values Breakdown
So now that we’ve looked at how the capacitor is actually changing the signal, and being selective about it with the help of a variable resistor, let’s get the numbers down. Each capacitor is going to have two numbers associated with it – the value and the voltage. Before we get into the important matters, I want to just narrow your scope of interest and point out that the voltage rating on a capacitor is not going to matter 99% of the time when it comes to electric guitars.
Why?
The voltage rating is essentially the amount of electricity that can come through at any given time before it burns out or degrades. A passive guitar’s circuit is only putting in a few volts, so generally any rating over 6 or 7 volts is enough…I can’t remember a time when I even came across a capacitor that wouldn’t be more than suitable. Active pickups put slightly more power into the circuit, usually thanks to a 9v battery.
Sometimes pickup setups are modified to run two 9 volt batteries – still just about nothing when considering that most capacitors are made to handle voltage by the hundreds.
The value of a capacitor is either written right on the thing or marked with some bands of color that you can decode. Paper in Oil capacitors will often have an alphanumeric code associated with them that you can just run through Google for a quick identification, but Ceramic, Electrolytic, Tantalum, Mica, and Poly Film caps are going to have bands of color that require a bit of math to work out. The following charts will help decode electrolytic and poly film caps (read here for the rest):
Capacitor Value Codes
Tolerance
(T) < 10pf
Capacitor Voltage Color Codes
If you’d like to learn more about the color code system, I’d recommend reading this guide from Electronics Tutorials. And if you’d prefer to skip all that and just get some quick help in identifying a mystery cap, use this code calculator.
The value of a capacitor is measured in Farads, but the capacitances we’re dealing with for our humble guitar circuits are small and are most commonly measured in Microfarads (µF) or Picofarads (pF). If you’re trying to go from one to the other, one picofarad is 1 millionth of a microfarad (ex. 4700pF = .047µF). Here’s the most common values:
Capacitor Voltage Color Codes
Smd Capacitor Code Chart
As the capacitance goes up, the tone gets darker. You’ll know why if you didn’t skip my long-winded explanation at the start. Speaking of common values, here’s a rule of thumb (and another variable to bore you with): pot rating! Normally you’re going to see guitar companies using 250k pots for single coil pickups and 500k pots for humbuckers. With an identical signal being passed through 250k and 500k variable resistors, you can expect the tone of the 250k pot to be darker while the 500k will be brighter.
The reason for that tangent is because you’ll find manufacturers also pair particular cap values with the pot size:
The practice of pairing the caps with the pots in such a way isn’t counterintuitive (darker pot with darker cap?) but simply the setup being tuned to reflect the pickup’s tonal qualities. Many people suggest first experimenting with caps that are lower than the standard value that came with your guitar because it’s going to produce the most dramatic difference. I like to make a little variable cap selector with a rotary knob and use a couple of alligator clips to put it in the circuit after removing the original capacitor, that way I can test out a bunch of tones without much hassle. Most of the time, I don’t know which values I’m selecting…and I like that because it keeps me focused on what’s truly important.
You are probably wondering if the right tone pot and capacitor could touch on all the sounds you might be trying to achieve with different capacitors. The cap affects tone even when the tone knob is all the way open, so choosing your value is important. You aren’t changing the value of the cap with a variable resistor, just the frequencies that are let through to be bled off or kept in the circuit by the cap’s value.
So far we have a lot of variables to consider: 1. Pickups, 2. Pots, 3. Cap values. All are contributing to the end product in their own way, and knowing how they work can save you a lot of time when you’re trying to achieve a particular voice. The reason I put numbers on them is because that’s the sequence in which they should be considered…you can just go down the line. It also happens to order each component by how much it affects your tone. Pickups are obviously the most important, but does that mean the capacitor is something that doesn’t really make a difference one way or another? YouTube provides plenty of evidence for the tone cap ‘hype’ (as the critics call it). A good starting point is this four part series here. I’ll give my personal opinion on tonal differences a bit later, but for now we can make a smooth transition into…
Understanding the Brands & Types of Capacitors for Guitars
When you start Googling around for tone caps, you’re going to see a lot of hype around Orange Drops, Bumblebees, and other nicknames that are mostly based on the cap colors. You’re also going to hear a LOT of different material names: mylar, metalized polyester, electrolytic, tantalum, paper in oil, etc.
I’m going to reorganize all this info here for you now to make your life slightly easier. There are four main categories to consider:
Polypropylene
Polystyrene
Metalized Polyester Film [made with Mylar]
Mylar [DuPont’s branded polyester]
A tone that is described as ‘bright’.
Polystyrene variants reported to have some interesting frequency loss characteristics in higher ranges.
‘Dark’, ‘warm’, ‘smooth’ tone.
Shortest shelf-life.
Most prone to DC leakage.
Described as ‘the brightest’ sound.
Also described as ‘anemic’.
Common due to their cheapness – generally not held in high regard among capacitor enthusiasts.
Ceramic Capacitor Code Chart
Aluminum
Tantalum
Niobium
Technically, they are paper in oil – but their differences in material and function warrant their own category.
Short shelf life – prone to burnouts when used after a long period of disuse.
Polarity sensitive – correct installation required.
DC Leakage.
Tantalum described as the superior electrolytic cap.
Often avoided due to their polarity issues.
There seems to be a few people touting a brand called V-Caps which uses various materials in their products: Teflon film, copper, metalized polypropylene, and tin foil.
Their materials and construction are probably most similar Orange Drops and Poly Film caps in general – I don’t know anything else about them except that they’re designed specifically for audio applications, which sets them apart from most other caps…they may be worth a listen.
Smd Capacitor Code Chart Pdf
Paper and wax caps are another option that have had some good reviews in electric guitar modification. I haven’t gotten around to trying them yet either.
Tonal Qualities of Capacitors
Finally, we come to the end. I saved this for last because it’s a matter of controversy and I’m not taking sides, but I cannot write about tone caps and not talk about the market.
Many guitarists and audiophiles alike are convinced of the specific, unique tonal qualities that can be found in particular brands of caps, ‘vintage’ caps / specific years of manufacturing, and the like. I spoke about a few of these disputed qualities above while I was describing the different categories of capacitors you’re likely to come across.
Does a .047µF paper in oil cap sound any different than a ceramic cap with the same exact value? Does a .022µF Orange Drop sound different than any other poly film cap?
Some people attribute the apparent differences noted in ‘vintage’ caps compared to brand new caps of the same brand, type, and marked value to be the result of degradation that has changed the actual value slightly. The DC leakage marked above as a detractor has been suggested as a possible reason for preferences being formed around aged caps as well.
Here’s a couple differing opinions that I feel have gone the extra mile in attempting to shut the other down: Gibson argues FOR the tonal differences, while a couple of audiophiles named Hank Wallace and Chad Barbour have made a tremendous effort AGAINST these claims.
What do I think? I don’t want to sway anyone one way or another, but I strongly suggest trying out different capacitor values either way because it’s entirely undisputed that changing the amount of treble bleed through different levels of capacitance has a noticeable effect on your tone.
Capacitor Code Chart Pdf
But while you’re at it, try out a few different types as well because there’s no reason not to find out for yourself while you’re already making the effort – you may discover something great.
Here is my complete conversion chart for all standard capacitor values. This chart allows one to convert between picofarads, nanofarads, and microfarads. With all the values listed here, you will not have any need to use a calculator.
picofarads | nanofarads | microfarads |
1.0 pF | 0.0010 nF | 0.0000010 uF |
1.1 pF | 0.0011 nF | 0.0000011 uF |
1.2 pF | 0.0012 nF | 0.0000012 uF |
1.3 pF | 0.0013 nF | 0.0000013 uF |
1.5 pF | 0.0015 nF | 0.0000015 uF |
1.6 pF | 0.0016 nF | 0.0000016 uF |
1.8 pF | 0.0018 nF | 0.0000018 uF |
2.0 pF | 0.0020 nF | 0.0000020 uF |
2.2 pF | 0.0022 nF | 0.0000022 uF |
2.4 pF | 0.0024 nF | 0.0000024 uF |
2.7 pF | 0.0027 nF | 0.0000027 uF |
3.0 pF | 0.0030 nF | 0.0000030 uF |
3.3 pF | 0.0033 nF | 0.0000033 uF |
3.6 pF | 0.0036 nF | 0.0000036 uF |
3.9 pF | 0.0039 nF | 0.0000039 uF |
4.3 pF | 0.0043 nF | 0.0000043 uF |
4.7 pF | 0.0047 nF | 0.0000047 uF |
5.1 pF | 0.0051 nF | 0.0000051 uF |
5.6 pF | 0.0056 nF | 0.0000056 uF |
6.2 pF | 0.0062 nF | 0.0000062 uF |
6.8 pF | 0.0068 nF | 0.0000068 uF |
7.5 pF | 0.0075 nF | 0.0000075 uF |
8.2 pF | 0.0082 nF | 0.0000082 uF |
9.1 pF | 0.0091 nF | 0.0000091 uF |
10 pF | 0.010 nF | 0.000010 uF |
11 pF | 0.011 nF | 0.000011 uF |
12 pF | 0.012 nF | 0.000012 uF |
13 pF | 0.013 nF | 0.000013 uF |
15 pF | 0.015 nF | 0.000015 uF |
16 pF | 0.016 nF | 0.000016 uF |
18 pF | 0.018 nF | 0.000018 uF |
20 pF | 0.020 nF | 0.000020 uF |
22 pF | 0.022 nF | 0.000022 uF |
24 pF | 0.024 nF | 0.000024 uF |
27 pF | 0.027 nF | 0.000027 uF |
30 pF | 0.030 nF | 0.000030 uF |
33 pF | 0.033 nF | 0.000033 uF |
36 pF | 0.036 nF | 0.000036 uF |
39 pF | 0.039 nF | 0.000039 uF |
43 pF | 0.043 nF | 0.000043 uF |
47 pF | 0.047 nF | 0.000047 uF |
51 pF | 0.051 nF | 0.000051 uF |
56 pF | 0.056 nF | 0.000056 uF |
62 pF | 0.062 nF | 0.000062 uF |
68 pF | 0.068 nF | 0.000068 uF |
75 pF | 0.075 nF | 0.000075 uF |
82 pF | 0.082 nF | 0.000082 uF |
91 pF | 0.091 nF | 0.000091 uF |
100 pF | 0.10 nF | 0.00010 uF |
110 pF | 0.11 nF | 0.00011 uF |
120 pF | 0.12 nF | 0.00012 uF |
130 pF | 0.13 nF | 0.00013 uF |
150 pF | 0.15 nF | 0.00015 uF |
160 pF | 0.16 nF | 0.00016 uF |
180 pF | 0.18 nF | 0.00018 uF |
200 pF | 0.20 nF | 0.00020 uF |
220 pF | 0.22 nF | 0.00022 uF |
240 pF | 0.24 nF | 0.00024 uF |
270 pF | 0.27 nF | 0.00027 uF |
300 pF | 0.30 nF | 0.00030 uF |
330 pF | 0.33 nF | 0.00033 uF |
360 pF | 0.36 nF | 0.00036 uF |
390 pF | 0.39 nF | 0.00039 uF |
430 pF | 0.43 nF | 0.00043 uF |
470 pF | 0.47 nF | 0.00047 uF |
510 pF | 0.51 nF | 0.00051 uF |
560 pF | 0.56 nF | 0.00056 uF |
620 pF | 0.62 nF | 0.00062 uF |
680 pF | 0.68 nF | 0.00068 uF |
750 pF | 0.75 nF | 0.00075 uF |
820 pF | 0.82 nF | 0.00082 uF |
910 pF | 0.91 nF | 0.00091 uF |
1000 pF | 1.0 nF | 0.0010 uF |
1100 pF | 1.1 nF | 0.0011 uF |
1200 pF | 1.2 nF | 0.0012 uF |
1300 pF | 1.3 nF | 0.0013 uF |
1500 pF | 1.5 nF | 0.0015 uF |
1600 pF | 1.6 nF | 0.0016 uF |
1800 pF | 1.8 nF | 0.0018 uF |
2000 pF | 2.0 nF | 0.0020 uF |
2200 pF | 2.2 nF | 0.0022 uF |
2400 pF | 2.4 nF | 0.0024 uF |
2700 pF | 2.7 nF | 0.0027 uF |
3000 pF | 3.0 nF | 0.0030 uF |
3300 pF | 3.3 nF | 0.0033 uF |
3600 pF | 3.6 nF | 0.0036 uF |
3900 pF | 3.9 nF | 0.0039 uF |
4300 pF | 4.3 nF | 0.0043 uF |
4700 pF | 4.7 nF | 0.0047 uF |
5100 pF | 5.1 nF | 0.0051 uF |
5600 pF | 5.6 nF | 0.0056 uF |
6200 pF | 6.2 nF | 0.0062 uF |
6800 pF | 6.8 nF | 0.0068 uF |
7500 pF | 7.5 nF | 0.0075 uF |
8200 pF | 8.2 nF | 0.0082 uF |
9100 pF | 9.1 nF | 0.0091 uF |
10000 pF | 10 nF | 0.010 uF |
11000 pF | 11 nF | 0.011 uF |
12000 pF | 12 nF | 0.012 uF |
13000 pF | 13 nF | 0.013 uF |
15000 pF | 15 nF | 0.015 uF |
16000 pF | 16 nF | 0.016 uF |
18000 pF | 18 nF | 0.018 uF |
20000 pF | 20 nF | 0.020 uF |
22000 pF | 22 nF | 0.022 uF |
24000 pF | 24 nF | 0.024 uF |
27000 pF | 27 nF | 0.027 uF |
30000 pF | 30 nF | 0.030 uF |
33000 pF | 33 nF | 0.033 uF |
36000 pF | 36 nF | 0.036 uF |
39000 pF | 39 nF | 0.039 uF |
43000 pF | 43 nF | 0.043 uF |
47000 pF | 47 nF | 0.047 uF |
51000 pF | 51 nF | 0.051 uF |
56000 pF | 56 nF | 0.056 uF |
62000 pF | 62 nF | 0.062 uF |
68000 pF | 68 nF | 0.068 uF |
75000 pF | 75 nF | 0.075 uF |
82000 pF | 82 nF | 0.082 uF |
91000 pF | 91 nF | 0.091 uF |
100000 pF | 100 nF | 0.10 uF |
110000 pF | 110 nF | 0.11 uF |
120000 pF | 120 nF | 0.12 uF |
130000 pF | 130 nF | 0.13 uF |
150000 pF | 150 nF | 0.15 uF |
160000 pF | 160 nF | 0.16 uF |
180000 pF | 180 nF | 0.18 uF |
200000 pF | 200 nF | 0.20 uF |
220000 pF | 220 nF | 0.22 uF |
240000 pF | 240 nF | 0.24 uF |
270000 pF | 270 nF | 0.27 uF |
300000 pF | 300 nF | 0.30 uF |
330000 pF | 330 nF | 0.33 uF |
360000 pF | 360 nF | 0.36 uF |
390000 pF | 390 nF | 0.39 uF |
430000 pF | 430 nF | 0.43 uF |
470000 pF | 470 nF | 0.47 uF |
510000 pF | 510 nF | 0.51 uF |
560000 pF | 560 nF | 0.56 uF |
620000 pF | 620 nF | 0.62 uF |
680000 pF | 680 nF | 0.68 uF |
750000 pF | 750 nF | 0.75 uF |
820000 pF | 820 nF | 0.82 uF |
910000 pF | 910 nF | 0.91 uF |
1000000 pF | 1000 nF | 1.0 uF |
1100000 pF | 1100 nF | 1.1 uF |
1200000 pF | 1200 nF | 1.2 uF |
1300000 pF | 1300 nF | 1.3 uF |
1500000 pF | 1500 nF | 1.5 uF |
1600000 pF | 1600 nF | 1.6 uF |
1800000 pF | 1800 nF | 1.8 uF |
2000000 pF | 2000 nF | 2.0 uF |
2200000 pF | 2200 nF | 2.2 uF |
2400000 pF | 2400 nF | 2.4 uF |
2700000 pF | 2700 nF | 2.7 uF |
3000000 pF | 3000 nF | 3.0 uF |
3300000 pF | 3300 nF | 3.3 uF |
3600000 pF | 3600 nF | 3.6 uF |
3900000 pF | 3900 nF | 3.9 uF |
4300000 pF | 4300 nF | 4.3 uF |
4700000 pF | 4700 nF | 4.7 uF |
5100000 pF | 5100 nF | 5.1 uF |
5600000 pF | 5600 nF | 5.6 uF |
6200000 pF | 6200 nF | 6.2 uF |
6800000 pF | 6800 nF | 6.8 uF |
7500000 pF | 7500 nF | 7.5 uF |
8200000 pF | 8200 nF | 8.2 uF |
9100000 pF | 9100 nF | 9.1 uF |
Choosing capacitor values can be a real headache for most hobbyists, and engineers. 'What are the standard values?' is something I end up asking myself sometimes.
Ceramic Capacitor Code Chart
It is even worse when you have to go around the shops looking for the value you need, because some shops might list it in pF whilst others use nF, so you end up converting between picofarads, nanofarads, and microfarads to figure out if it is the same thing.
Capacitor Code Chart
Well, fear no more, because Pete is here and I decided to make a complete chart for the E24 series. There was no site on any search engine with such a chart showing every value together with the conversion. The calculations took me ages to do in my head so let us hope someone finds it useful.