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Here you go. (Attachment Link)
I'm using tantalum caps, not an ESU Power Pack. So, I'm only using the GND and Blue/U+ connections. So far, it makes for quite a fireworks display...
I only use about 400 to 450 uF of poly tantalum caps, so I don’t use the added resistor and diode as shown on this picture. (Attachment Link)
After pondering this more, in the absence of the resistor, how is the cap not seen as a dead short to a non-DC signal? DC would see it as an open. @peteski ? Without a current-limiting resistor, wouldn't the inrush current blow the cap all by itself? Chris
Chris, decoders are micro computers -- they require DC power to function. Same with the motor and function-powered devices.Every decoder has a bridge rectifier which takes the DCC pulses and rectifies them into a DC voltage. The decoder also has some fairly small value filter caps connected at the DC side of the bridge rectifiers to smooth out the voltage. That is also the location where you connect additional Keep-alive circuit. Those are either some larger value capacitors which will store enough energy to keep the decoder's electronics from resetting during very brief power pickup interruptions (dirty track), or a SuperCap-based keep-alive circuit which stores enough energy to keep the entire model functional (the decoder's electronic, motor and function outputs) for few seconds.That is why you don't have to worry about the capacitor blowing up*. Inrush current is also not the correct term used when AC voltage is applied to a cap. Inrush current occurs when a DC-voltage is applied to a discharged capacitor. At that point the "empty" capacitor will "suck up" as much current as it can. That current limited by the capacitor's internal resistance, and by the external resistance between the cap and the source of power. But that current spike is very short (it depends on how large the capacitance is). As the capacitor charges (fills up with electric charge) the current decreases until it is zero when the cap is fully charged.With the keep-alive caps we use in N scale trains (usually less than 1000 micro Farads) we don't really have to worry much about the inrush current. For larger value caps, the circuit Steve posted is used. That resistor/diode circuit is also used in the SuperCap-based keep-alives.I like to add a coil in series with he cap. Coils pass DC voltage, but exhibits higher resistance (impedance) to any change in the current passing through them, like the current pulses which occur during programming on programming track. Adding a coil usually makes programming possible without disconnecting the keep-alive capacitors.* No guarantees that a tantalum cap will not flame up inside the model. That is usually caused by defective cap, and applying voltage that is too close to the cap's max. operating voltage.
@peteski @Steveruger45 I hooked up my VMM to the the decoder where I'm connecting the caps, and got about 13.7v. Polarity also checked out as expected - + on blue, 1 on GND. In the absence of a power tool battery, I have an old MRC power pack with a fixed DC-output that measured 15v. So, I connected that to a cap from the batch I've been using, making sure to connect positive to the anode and negative the cathode. After about 10 minutes... nothing. It didn't blow. They've been blowing within a few seconds on the locomotive. I'm still at a loss... Ideas? I appreciate your help, gentlemen! Chris