A method includes pre-charging a parasitic capacitance of a control node that is coupled to a control terminal of first and second transistors that have respective current paths that form a switched current path coupled between a load node and a storage node. Pre-charging the parasitic capacitance includes: making conductive a first auxiliary transistor that has a current path coupled between the storage node and the control node, or making conductive a second auxiliary transistor that has a current path coupled between the load node and the control node. The method further includes, after pre-charging the parasitic capacitance, making the switched current path conductive to couple the load node to the storage node.

An electronic read circuit for a radiation detector comprises: an element sensitive to the radiation, an injection circuit, able to inject a charge at one terminal of the sensitive element, the injection circuit extending between at least one input terminal and one output terminal, the output terminal being able to be connected to the sensitive element, the injection circuit being able to produce a charge under the effect of a trigger pulse. The injection circuit is able to inject a first charge when an input terminal is connected to a first input potential and a second charge when an input terminal is connected to a second input potential. The circuit comprises means for storing a difference between an output potential of the injection circuit, called equilibrium potential, and a reference potential, such that the second charge depends on the second input potential and on the equilibrium potential.

In accordance with an embodiment, a method includes receiving an enable signal. After the enable signal is asserted, it is determined whether a soft-start capacitor is electrically connected to an input of a ramp generator circuit while keeping an output of the ramp generator circuit low. If the soft-start capacitor is electrically connected to the input of the ramp generator circuit, a first current is injected into the input of the ramp generator circuit to generate a first voltage ramp at the output of the ramp generator circuit. If the soft-start capacitor is not electrically connected to the input of the ramp generator circuit, a second current is injected to the input of the ramp generator circuit to generate a second voltage ramp at the output of the ramp generator circuit. The second current is smaller than the first current.

A driving circuit is a circuit selectively outputting one of a staircase wave and a square wave from an output terminal, to drive a capacitive load, and includes a first power source supplying a constant voltage VH, a first FET connected between the output terminal and the first power source, a first transformer in which an output side coil is connected to a gate of the first FET, a first input terminal connected to an input side coil of the first transformer via a capacitive element, a second power source supplying a constant voltage VL, a second FET connected between the output terminal and the second power source, a second transformer in which an output side coil is connected to a gate of the second FET, and a second input terminal connected to an input side coil of the second transformer via a capacitive element.

The disclosure relates to a square wave RC oscillator circuit, example embodiments of which include an oscillator circuit for generating an output square wave signal (OUT) having first and second voltage output levels (L, H), the oscillator circuit comprising: a comparator having an output and first and second inputs; a switching circuit configured to provide an oscillatory waveform at the first input of the comparator; and a feedback circuit arranged to sample the first input of the comparator each time the output square wave signal (OUT) switches between the first and second voltage output levels (L, H) and to compare this sampled voltage with first and second reference voltages (V.sub.A, V.sub.B) to adjust a voltage provided to the second input of the comparator.

The disclosure relates to a square wave RC oscillator circuit, example embodiments of which include an oscillator circuit for generating an output square wave signal (OUT) having first and second voltage output levels (L, H), the oscillator circuit comprising: a comparator having an output and first and second inputs; a switching circuit configured to provide an oscillatory waveform at the first input of the comparator; and a feedback circuit arranged to sample the first input of the comparator each time the output square wave signal (OUT) switches between the first and second voltage output levels (L, H) and to compare this sampled voltage with first and second reference voltages (V.sub.A, V.sub.B) to adjust a voltage provided to the second input of the comparator.

A ramp signal generation device includes a sampling circuit suitable for sampling a ramp current, which flows on a plurality of ramp current paths, and storing a voltage corresponding to the sampled ramp current; a current maintaining circuit suitable for maintaining the ramp current; a current maintaining/transferring circuit suitable for maintaining and transferring a current corresponding to the voltage stored by the sampling circuit; a selection circuit suitable for selecting a ramp current path of the sampling block and the current maintaining/transferring circuit; and a current-to-voltage converter suitable for converting the current transferred from the current maintaining/transferring circuit and generating therefrom a ramp voltage.

Methods and devices for performing ablation. In some examples an ablation delivery system is configured to allow separate voltage levels of a capacitor stack to be accessed for use in therapy delivery. Ablation therapy systems switchable between current and voltage controlled output are described. Methods of treating a patient using adjustable interphase or interpulse delay are disclosed as well.

A data retention circuit includes a power switch, a first inverter and a second inverter. The power switch has a first connection terminal coupled to a power voltage, and a second connection terminal coupled to the first power terminal and a second power terminal of a second inverter. The second input terminal and the second output terminal of the second inverter are coupled to the first output terminal and the first input terminal of the first inverter, respectively. In a sleep mode, the power switch and the transistor are turned off, a first leakage current flows between the first connection terminal and the second connection terminal, a second leakage current flows between the first power terminal and the first output terminal, and the first and the second leakage currents form a steady-state voltage, higher than or equal to a data retention voltage, on a second connection terminal.

In an embodiment, a method includes pre-charging a parasitic capacitance of a control node that is coupled to a control terminal of first and second transistors that have respective current paths that form a switched current path coupled between a load node and a storage node. Pre-charging the parasitic capacitance includes: making conductive a first auxiliary transistor that has a current path coupled between the storage node and the control node, or making conductive a second auxiliary transistor that has a current path coupled between the load node and the control node. The method further includes, after pre-charging the parasitic capacitance, making the switched current path conductive to couple the load node to the storage node.