This is a circuit design for a typical wall-plug power adapter.

The sinusoidal source represents a typical US 60 Hz, 120V AC wall supply.

A transformer steps the voltage down to a manageable range to be rectified for a 5V DC supply, but the waveform is still sinusoidal.

The 4 diode bridge rectifier takes this lower amplitude sinusoidal signal and produces a DC biased result, but still with noise resulting from the rectification process.

The capacitor before the voltage regulator chip helps smooth some of this noise. Then the regulator chip provides a self-contained, feedback controlled mechanism to keep the output voltage at the specified value.

The output capacitor further smooths any output ripple and provides a reservoir of charge to supply any surge in current load that may be encountered.

This example includes a load resistor that allows the exploration of the effects of load. The load is varied during the simulation and it can be seen that above a load of 100 mA, the regulation of the output voltage begins to deteriorate.

The addition of a few components can make it possible for such a circuit to provide significantly higher power loads. See http://www.systemvision.com/design/ac-dc-power-adapter-current-boost-regulator for an example.

This design will examine the "constant on time" control methodology applied to a buck converter. This type of control is often used when large input or output voltage ranges are specified. This type of control is based on hysteretic control and requires no compensation, but results in a variable switching frequency.

A DC assimetric 15V linear power supply eazy to make.

Can drive a 0.33ohm load without voltage decay (not reccomended try)

                     Ratings:

symbol /  test condition  /   typ  /  unit

Pd       / 4 ohm load         /   55   /  W

Pd        / 8 ohm load        /   27   /  W

Pd        /1kilo ohm load   /  2,5  /   W 

Ic         / 4 ohm load        /  3.73 /   A

Ic         / 8 ohm load        / 1.86 /    A

Ic         / 1kilo ohm load  /  15.0 / mA

*Use huge dissipator on the transistor

*U can use various transistors in paralel, however use an resistor on emitter

This is a circuit design for a typical wall-plug power adapter.

The sinusoidal source represents a typical US 60 Hz, 120V AC wall supply.

A transformer steps the voltage down to a manageable range to be rectified for a 5V DC supply, but the waveform is still sinusoidal.

The 4 diode bridge rectifier takes this lower amplitude sinusoidal signal and produces a DC biased result, but still with noise resulting from the rectification process.

The capacitor before the voltage regulator chip helps smooth some of this noise. Then the regulator chip provides a self-contained, feedback controlled mechanism to keep the output voltage at the specified value.

The output capacitor further smooths any output ripple and provides a reservoir of charge to supply any surge in current load that may be encountered.

This example includes a load resistor that allows the exploration of the effects of load. The load is varied during the simulation and it can be seen that above a load of 100 mA, the regulation of the output voltage begins to deteriorate.

The addition of a few components can make it possible for such a circuit to provide significantly higher power loads. See http://www.systemvision.com/design/ac-dc-power-adapter-current-boost-regulator for an example.

This is a circuit design for a typical wall-plug power adapter.

The sinusoidal source represents a typical US 60 Hz, 120V AC wall supply.

A transformer steps the voltage down to a manageable range to be rectified for a 5V DC supply, but the waveform is still sinusoidal.

The 4 diode bridge rectifier takes this lower amplitude sinusoidal signal and produces a DC biased result, but still with noise resulting from the rectification process.

The capacitor before the voltage regulator chip helps smooth some of this noise. Then the regulator chip provides a self-contained, feedback controlled mechanism to keep the output voltage at the specified value.

The output capacitor further smooths any output ripple and provides a reservoir of charge to supply any surge in current load that may be encountered.

This example includes a load resistor that allows the exploration of the effects of load. The load is varied during the simulation and it can be seen that above a load of 100 mA, the regulation of the output voltage begins to deteriorate.

The addition of a few components can make it possible for such a circuit to provide significantly higher power loads. See http://www.systemvision.com/design/ac-dc-power-adapter-current-boost-regulator for an example.