BJT drive scheme

The invention claimed is: 1. A switching control circuit for a switch mode power converter (SMPC), a said SMPC having an inductive component having a winding coupled to receive power from an input to the SMPC, a bipolar transistor coupled to control current flow in the winding, an auxiliary power rail, a charge store for supplying power via the auxiliary rail to a switching control circuit for driving the bipolar transistor, and a bootstrap circuit for bleeding current from the input to the bipolar transistor to thereby provide an amplified current to the charge store, the switching control circuit comprising: a base current line for coupling to a base terminal of a said bipolar transistor, an emitter current line for coupling to an emitter terminal of a said bipolar transistor, an auxiliary line for coupling to a said auxiliary power rail, and at least one reference line for coupling to a reference voltage; a base current switch configured to controllably couple a base current source to the base current line; an emitter current switch configured to controllably couple the emitter current line to a said reference line; a bootstrap element for bleeding current from the emitter current line to the auxiliary line, the bootstrap element further operable to block a said current according to a current or voltage bias; a base discharge switch configured to controllably bleed current from the base current line to a said reference line; and a supplementary base drive line for coupling to a series circuit comprising a supplementary base drive resistor and current control element coupled in series, a said series circuit for bleeding current from a said input to a said base terminal, a said current control element for blocking current flow from a said bootstrap circuit to a said supplementary base drive resistor. 2. Switching control circuit of claim 1 , comprising at least one of the said supplementary base drive resistor and current control element coupled to the supplementary base drive line. 3. Switching control circuit of claim 1 , wherein the supplementary base drive line is additional to the base current line. 4. Switching control circuit of claim 1 , having a package comprising an integrated circuit having the switching control circuit, and comprising at least a said supplementary base drive resistor of a said series circuit, wherein at least the supplementary base drive resistor is external to the package. 5. Switching control circuit of claim 1 , wherein the current control element comprises a diode for performing said blocking when a said voltage bias reverse-biases the diode. 6. Switching control circuit of claim 1 , wherein the current control element comprises a supplementary base drive switch configured to receive the current or voltage bias as a control signal, the supplementary base drive switch controllable to performing said blocking according to the control signal. 7. Switching control circuit of claim 6 , wherein the switching control circuit is configured to synchronise switching of the base current switch and the supplementary base drive switch to turn on simultaneously to allow current flow to the base line. 8. Switching control circuit of claim 6 , wherein the switching control circuit is configured to control timing of switching both the base current switch and the supplementary base drive switch based on monitoring the SMPC, preferably wherein said monitoring comprises monitoring a signal on the auxiliary power rail and/or on a terminal of a said bipolar transistor, the switching control circuit thereby operable to regulate output power from a said SMPC. 9. Switching control circuit of claim 1 , comprising a charging circuit for supplying charge to the charge store for providing power to a switching controller of the switch mode power converter (SMPC), the SMPC comprising: an inductive component having a winding coupled to receive power from an input to said SMPC; a switching circuit comprising first and second switching transistors, said first transistor coupled in series between said winding and said second transistor and to receive a winding current wherein said winding current is a current derived from said winding; a switching controller to control switching of said second transistor; and a charge store coupled to provide power to said switching controller, the charging circuit comprising: a current diversion circuit to conduct a said winding current from the first transistor to said charge store; and said second transistor arranged to controllably decouple a reference voltage line from said current diversion circuit to allow said winding current to flow through said current diversion circuit to said charge store. 10. A switching control circuit of claim 1 , wherein said bleeding current by said series circuit comprises bleeding current from a said input via a said auxiliary power rail. 11. Switch mode power converter (SMPC) comprising the switching control circuit of claim 1 , wherein the SMPC is a flyback, forward or boost converter. 12. Method of providing supplementary base drive to a bipolar transistor of a switch mode power converter (SMPC), a said SMPC having an inductive component having a winding coupled to receive power from an input to the SMPC, a bipolar transistor coupled to control current flow in the winding, an auxiliary power rail, a charge store for supplying power via the auxiliary power rail to a switching controller having a base current switch to control current drive to the bipolar transistor, and a bootstrap circuit for bleeding current from the input to the bipolar transistor to thereby provide an amplified current to the charge store, the SMPC having a series circuit comprising a supplementary base drive resistor and a supplementary base drive switch coupled in series, the series circuit for bleeding current from a said input to a base terminal of the bipolar transistor, the supplementary base drive switch for blocking current flow from a said bootstrap circuit to the supplementary base drive resistor, the method comprising: turning the base current switch on to allow base current to pass to the bipolar transistor throughout an on time period; and driving the supplementary base drive switch on for at least part of the on time period, to thereby supplement the base current to thereby drive the bipolar transistor on. 13. The method of claim 12 , comprising: controlling the bipolar transistor off throughout an off time period; and driving the supplementary base drive switch on for at least part of the off time period, to allow current flow from the auxiliary power rail through the supplementary base current resistor to thereby reduce voltage on the auxiliary power rail. 14. The method of claim 12 , comprising monitoring voltage on the auxiliary power rail, and comprising: enabling said driving the supplementary base drive switch on or at least part of the off time period, when voltage on the auxiliary power rail is above a threshold voltage. 15. The method of claim 13 , comprising inhibiting said driving the supplementary base drive switch on for at least part of the off time period, when voltage on the auxiliary power rail is below a threshold voltage. 16. The method of claim 12 , comprising a method of providing power to a switching controller of the switch mode power converter (SMPC), the SMPC having: the inductive component having a winding coupled to receive power from the input to said SMPC; a switching circuit comprising first and second switching transistors, said first transistor coupled in series between said winding and said second transistor