Don't use this one on the reservoir cap though, the higher inrush current will fry the LED!Ħ: Ok, this one isn't an LED, it's a neon lamp used as grid-to-cathode arc protection on a DC-coupled stage. The green LED will light for a couple of seconds at switch on as the capacitor charges, and the red LED will light at switch off.
#ANODE OR CATHODE LED FOR GUITAR PEDAL SERIES#
The LED will be off normally, but will light up as the capacitor discharges at switch off, providing a warning while the cap is still holding chargeĥ: A dual-colour LED in series with a smoothing capacitor. A rectifier diode is also added in parallel to allow normal operation of the cap. The LED will slowly come on as the valve warms up.Ĥ: In series with a smoothing capacitor. Although this will raise the cathode voltage by a tiny amount, it is usually insignificant in terms of normal circuit operation. The LED will slowly come on as the valve warms up.ģ: In series with a cathode load resistance/tail resistance. Obviously this has the same effect as a bias resistor with a perfect bypass capacitor, so carries tonal considerations. The LED will slowly come on as the valve warms up.Ģ: LED bias. For normal values of anode resistor, this will have no effect on tone / operation. The different applications are numbered:ġ: In series with the anode. The schematic below shows a simple preamp (albeit with some Valve Wizard tricks incorporated) and shows some fun ways in which LEDs can be incorporated, usually with no impact on the tone of the amp. It is advisable to use a value which is somewhat greater than indicated, to be on the safe side. First, take your DC input voltage to the regulator and then subtract the regulator's output voltage from it, then read off the capacitance for the required output current. The graph below shows the absolute minimum required reservoir capacitance when using a conventional IC regulator, to avoid the regulator switching off at any time. Q1 can be any general purpose PNP, e.g., 2N3906. A 24V relay is shown, but other voltages could be used simply change the zener voltage to match the relay voltage. This circuit will drive up to 60mA relays with 230V mains, or up to 30mA relays with 120V mains. Both electrolytics only have to withstand the zener voltage, so can be low-voltage types.
When the mains is switched on, the time delay before the relay actuates is determined by C1, and is about 0.5seconds per 100uF. It operates directly from the mains via an X-class capacitor which serves as a wattless dropper. This graph shows how the gain of a typical ECC83 varies with anode resistor when loaded by various following AC load resistances.īelow: A useful chart for converting a fret / note to frequency (zero decimal places).īelow is a simple circuit for a time-delay relay. This graph shows how the frequency reponse of a typical ECC83 with 100k anode load and 1.5k cathode resistor, for different values of cathode bypass capcitor. Here I intend to keep useful bits and pieces, whenever they come up.
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