Tapped inductor, boost regulator deliver high voltage

When you face the task of generating a regulated voltage that's higher than the available power-supply voltage, you may consider a boost regulator. Although a boost converter can in theory generate almost any voltage that's higher than its input, practical considerations limit the output to approximately eight times its applied voltage. To generate an even higher voltage, consider using a tapped-inductor boost topology. Figure 1 shows an implementation of a converter that boosts a 3V input to 100V dc. The connections to the regulator chip are similar to those of a traditional boost converter, but, to achieve the high boost ratio, this design uses L₁, a 1- to-6-turns-ratio, tapped inductor.

The waveforms in Figure 2 show the input voltage, the voltage at power-switch IC₁'s output, Pin 5, and rectifier diode D1's anode voltage. As in any boost circuit, inductor L₁'s core stores energy when IC₁'s internal output switch conducts. When the switch turns off, the voltage across its terminals and L_1A goes higher than the input voltage. Due to inductive coupling and the larger number of turns that make up L_1B, the voltage at rectifier diode D1's anode and hence the output voltage goes much higher. Resistors R2 and R3 form a feedback-voltage divider that closes the regulation loop. The R4–C4 network forms a snubber circuit that suppresses the impact of diode D1's small parasitic capacitance. Without the network, power switch IC₁ “seesâ€� a capacitance that's 36 times larger due to the multiplicative effect of the tapped inductor's turns ratio.

Measuring only 5.6x6x3.4- mm, Coiltronics' CTX02-17409 tapped inductor, L₁, and Linear Technology's LT1949 monolithic regulator, IC₁, available in an eightlead MSOP package, present small pc-board footprints. When you implement the circuit on a singlelayer pc board, the entire circuit occupies less than 1.9cm2 of board space (Figure 3). For best results, review the board-layout suggestions in the device's data sheet (Reference 1) and use multilayerceramic capacitors for C₁ and C₃.

Reference
1. www.linear.com/pc/productDetail.do?navId=H0,C1,C1003,C1042,C1031,C1061,P1958.