Load switch with self-resetting circuit breaker
The simple current-limiting load switch shown in Figure 1 will be familiar to most readers. In this circuit, a high level signal applied to the input switches on MOSFET Q2, which energizes the load. The load current is limited by negative feedback applied via Q1.
In most applications, the current flowing via R2 into Q1’s base will be very small compared to the load current IL, so the voltage VCS developed across current-sensing resistor RCS is roughly equal to Q1’s base-emitter voltage, VBE. Therefore, VBE ≈ VCS, and since VCS = ILRCS, it follows that VBE ≈ ILRCS, or IL ≈ VBE / RCS.
The value of RCS is chosen to limit the load current to a maximum value determined by IL(max) ≈ VBE(on) / RCS, where VBE(on) is the base-emitter voltage needed to bias Q1 into conduction. At room temperature, VBE(on) ≈ 650mV. So, for example, a value of RCS = 3.3Ω would set IL(max) to around 200mA.
Under normal, ‘no-fault’ conditions, where IL is within normal limits, VBE is too small to bias Q1 on, such that MOSFET Q2 remains fully enhanced by the high level signal applied to its gate via R1. Under these conditions, the load current is determined mainly by the load resistance and the supply voltage, VS. However, if a fault causes IL to approach IL(max), Q1 starts to conduct, and reduces Q2’s gate-source voltage to a level that holds the load current roughly constant, at a value given by IL(max) ≈ VBE(on) / RCS.
For more detail: Load switch with self-resetting circuit breaker