Class D audio amplifier with overload protection circuit

What is claimed is: 1. A class D audio amplifier, comprising: an input node or terminal configured to receive an audio signal; a modulator configured to convert the audio signal into a modulated audio signal having a carrier or modulation frequency; an output stage comprising a plurality of power transistors coupled in cascade between a first DC supply voltage and a second DC supply voltage; a plurality of gate drivers comprising respective inputs coupled to the modulated audio signal and configured to generate respective modulated gate drive signals to the plurality of power transistors; a first overload protection circuit comprising a model transistor having electric characteristics representative of a first power transistor of the output stage, wherein the first overload protection circuit is configured to: repeatedly determine a drain-source reference voltage of the model transistor; compare the drain-source reference voltage of the model transistor with a drain-source voltage of the first power transistor; generate an overload signal based on the comparison between the drain-source reference voltage of the model transistor and the drain-source voltage of the first power transistor; and operate by an intermittent scheme comprising repeatedly switching between a tracking phase for determining a current drain-source reference voltage of the model transistor and a holding phase for storage of the current drain-source reference voltage of the model transistor until a subsequent tracking phase is initialized. 2. The class D audio amplifier of claim 1 , wherein the first overload protection circuit is configured to select a first bias current level through the model transistor during the tracking phase, and select a second bias current level, smaller than the first bias current level, through the model transistor during the holding phase. 3. The class D audio amplifier of claim 2 , wherein a duration of the holding phase is at least 10 times longer than a duration of the tracking phase. 4. The class D audio amplifier of claim 3 , wherein the duration of the holding phase is at least 50 times longer than the duration of the tracking phase. 5. The class D audio amplifier of claim 1 , wherein the first overload protection circuit is configured to transmit the overload signal to the gate driver of the first power transistor, and wherein the gate driver of the first power transistor comprises control logic responsive to the overload signal to selectively disconnect and interconnect gate and source terminals of the first power transistor based on a logic state of the overload signal. 6. The class D audio amplifier of claim 1 , wherein the drain-source reference voltage of the model transistor represents the drain-source voltage of the first power transistor at a predetermined target current through the first power transistor. 7. The class D audio amplifier of claim 6 , wherein the first overload protection circuit comprises a programmable or fixed current source configured to set a bias current of the model transistor, wherein the bias current is configured to place the model transistor in a triode-region operation, and wherein a width to length (W/L) ratio of the model transistor is at least 100 times smaller than a width to length (W/L) ratio of the first power transistor. 8. The class D audio amplifier of claim 7 , wherein the bias current of the model transistor is set to a predetermined fraction of the predetermined target current of the first power transistor, and wherein the predetermined fraction is derived from a ratio between the W/L ratio of the model transistor and the W/L ratio of the first power transistor. 9. The class D audio amplifier of claim 1 , wherein the first overload protection circuit is configured to estimate an overdrive voltage of the first power transistor, apply a predetermined fraction of the overdrive voltage to a gate terminal of the model transistor for supplying a fractional drain-source reference voltage, and wherein a DC multiplication circuit is configured to multiply the fractional drain-source reference voltage by the reciprocal of the predetermined fraction to generate the drain-source reference voltage of the model transistor. 10. The class D audio amplifier of claim 1 , wherein the first overload protection circuit comprises a holding capacitance configured to be charged to the current drain-source reference voltage of the model transistor during the tracking phase and to maintain the current drain-source reference voltage of the model transistor during the subsequent holding phase. 11. The class D audio amplifier of claim 1 , wherein the first overload protection circuit comprises: a subtraction circuit configured to subtract the drain-source reference voltage of the model transistor and the drain-source voltage of the first power transistor to provide a difference voltage; and a class B comparator coupled to the difference voltage and configured to generate the overload signal based on the difference voltage. 12. The class D audio amplifier of claim 11 , wherein the class B comparator comprises a first substantially unbiased state entered in response to a first polarity of the difference voltage, and a second actively biased state entered in response to a second polarity of the difference voltage. 13. The class D audio amplifier of claim 1 , wherein the plurality of power transistors at least comprises: a second power transistor having an opposite polarity of the first power transistor; and a second overload protection circuit configured to generate an overload signal for the second power transistor. 14. The class D audio amplifier of claim 1 , wherein the output stage comprises an upper leg and a lower leg electrically interconnected at a midpoint node, the midpoint node being connectable to a loudspeaker load. 15. A method of protecting a first power transistor of an output stage of a class D audio amplifier against overload current, the method comprising: applying an audio input signal to the class D audio amplifier; modulating the audio input signal to generate a modulated audio signal at a predetermined carrier or modulation frequency; deriving, from the modulated audio signal, a modulated gate drive signal for the first power transistor of the output stage to repeatedly switch the first power transistor between a conducting state and a non-conducting state; repeatedly determining a drain-source reference voltage of a model transistor possessing electric characteristics representative of the first power transistor; comparing the drain-source reference voltage of the model transistor with a drain-source voltage of the first power transistor; generating an overload signal based on the comparison between the drain-source reference voltage of the model transistor and the drain-source voltage of the first power transistor; and repeatedly switching between a tracking phase for determining a current drain-source reference voltage of the model transistor and a holding phase for storage of the current drain-source reference voltage of the model transistor until a subsequent tracking phase is initialized. 16. The method of claim 15 , further comprising: transmitting the overload signal to a gate driver of the first power transistor; and selectively disconnecting and interconnecting gate and source terminals of the first power transistor via the gate driver based on a logic state of the overload signal. 17. The method of claim 15 , further comprising: subtracting the drain-source reference voltage of the model transistor an