Audio Analogue SRL BELLINI manual Virtual battery, AUDIO FUTURA spa

AUDIO FUTURA spa

Virtual battery

The target is to not have power supply interferences at all. The first step is to clean out the AC line, and this is what is done with an “AC filter”. But the solution is always expensive and cumbersome if we use a filter for all the audio chain and anyway doesn’t help in any way to eliminate the low frequencies problems. The perfect solution would be to not connect the unit to the AC line and take the supply from a battery, but this is impossible for power amplifier for evident reasons and not very useful for a preamplifier or audio source too.

To solve the problem we have designed a virtual battery power supply. That’s said a circuit that insulate completely the preamplifier power supply from the AC main.

How can you see in the schematic, the AC main is filtered just as it reaches the board to eliminate any high frequency disturbs. Then the AC voltage is reduced by the transformer to be used on the board, rectified by the bridge and then filtered. Then we found two voltage regulators one for the positive voltage and the other for the negative. The AREA1 is “contaminated” by the 50Hz (60Hz) presence. What we have done in this part is trying to eliminate the interference as more as possible, designing two discrete components voltage regulators (voltage regulators 1 and 2) with very high 50Hz/60HZ noise rejection. Until now nothing new under the sun, because these solutions are present with better or worse results in every good preamplifier, the virtual battery comes beyond. What we want to do is to never connect in any way the preamplifier power supply stage (that supplies the preamplifiers, the input selection circuit and the volume circuit) to the 50Hz/60Hz area.

This is implemented supplying the Voltage regulators 3 and 4 by a capacitor bank of 156000μF(!!!!).

The circuit worsk as follows:

∙at the turn on the control, that governs every switches and can sense the values of the voltage at the points V1 and V2, opens the switches 5, 6, 7 and 8 leaving the Voltage regulators 3 and 4 (and so all the preamp circuits) unpowered, while closing the switches 1, 2, 3, and 4. In such way after a delay all the capacitors in the four banks are charged.

∙Then the control open the switches 1 and 3 and closes the switches 5 and 7.So the AREA2 is powered by the banks B1 and B3 but is disconnected from Area1. The voltage regulators 3 and 4 works consuming the charge stored in the capacitors of the banks B1 and B3. So the voltage at point V1 and V2 decrease.

∙The control observes the voltage V1 and V2, and when they are too low the control switches off the switches 5 and 7 disconnecting the banks B1 and B3 from the AREA2, switches off the switches 2 and 4 disconnecting the banks B2 and B4 from the AREA1 and then switches on the switches: 6, 8 (connecting banks B2 and B4 to voltage regulators 3 and 4). Then the control close the switches 1 and 3 connecting the banks B1 and B3 to the Voltage regulators 1 and 2 and charging again the capacitors of the two banks.

During the switching time the voltage at the input of Voltage regulator 1 and 2 is supplied by the capacitor C1 and C2.