JPWO2018109185A5 - - Google Patents

Description

According to certain embodiments of such voltage converters,
-The tuning circuit is a control circuit having an output designed to deliver the activation signal and an output designed to deliver the result of the comparison, the first input of the control circuit. Further can be provided with a comparator circuit having said output connected to.
-The tuning circuit is an additional ripple circuit configured to deliver the converted voltage level to which the ripple voltage has been applied and is connected to the first terminal of the output port of the converter. To deliver the set signal with an additional ripple circuit having a first input, a second input connected to the output of the control circuit, and an output connected to the first input of the comparator circuit. An error amplifier designed for the first input connected to the first terminal of the output port of the converter, the second input configured to receive the reference voltage, and the comparator circuit. The amplifier having an output connected to a second input can be further provided.
-The control circuit is further configured to control the closing or opening of the first switch, the generation of the rising or falling voltage on the second input of the additional ripple circuit. May be good.
-The converter is a resonant inductor connected in series with the first switch, the first terminal, and the first terminal and the second terminal connected to the first switch. A resonance inductor having A second switch, which is connected to the first terminal of the capacitor and, on the other hand, is connected to the second terminal of the resonant capacitor, can be further provided.
-The converter may also include a low pass output filter.
-The adjustment circuit is a circuit for protecting from overload, and includes a circuit for measuring the current flowing through the second switch, a first input of a predetermined current limiting signal, and the first input. A comparator circuit having a second input, which is connected to the circuit for measuring the current flowing through the switch of 2, can be included, and the circuit for protection from overload can be included in the control circuit. Further having an output connected to a second input, the control circuit is to deliver a signal on that output in response to a comparison between the first input and the second input. It is configured to control the opening of the first switch as long as the signal representing the current flowing through the second switch is at least equal to the predetermined limiting current signal. More specifically, the current measuring circuit may include a resistor connected between the second terminal of the resonant capacitor and the ground wire.
-The converter is a flywheel diode connected in parallel to the first switch and may include a flywheel diode having a cathode connected to the first terminal of the first port. The predetermined period is selected to open the first switch as the current flowing through the first switch flows through the flywheel diode.
-The control circuit can be configured to open the first switch for a predetermined minimum period.
-The first switch and the second switch can exhibit a switching time of 100 ns or less, and preferably 10 ns or less. More specifically, the first switch and the second switch can be manufactured using GaN technology.

Additional Ripple Circuits Ond. Add. The first input of is connected to the first terminal 204 of the output port 206 of the converter, while the second input is also designed to deliver the start signal for the first switch Qhs. It is connected to the output of the control circuit 207. An electrical schematic of the additional ripple circuit is shown in FIG. The error amplifier MEA that allows the generation of the set signal Vcons has a first input connected to the reference voltage Vref and a second input connected to the first terminal 204 of the output port 206 of the converter. .. The comparator 210, which allows the first comparison to be performed, includes a first input connected to the output of the error amplifier MEA and an additional ripple circuit Ond. Add. It has a second input, which is connected to the output of. The output of the comparator 210 connected to the first input of the control circuit 207 closes the first switch when the decrease in the signal representing the addition of the voltage level and ripple after conversion is equal to the set signal Vcons. It supplies a binary signal representing the result of a first comparison that allows the generation of a controlled activation signal. In one embodiment, the control circuit 207 is a programmable circuit such as an FPGA (Field Programmable Gate Array). Since this adjustment is based on a comparator used in an unconditionally stable control mode, it is possible to control the output voltage at a very high speed. By adjusting at the maximum speed in this way, it becomes possible to form a converter having excellent dynamic performance characteristics. Static tuning performance is provided by the MEA, which modifies the settings applied to the comparator to obtain a fully tuned average output voltage. Protection of the conditioning circuit 211 from overload has a first input of a predetermined current limiting signal Illim and a second input connected to the circuit for measuring the current flowing through the second switch Qls. Includes comparator 212. The first switch Qhs cannot be controlled as long as the current I Qls is higher than Illim, thereby limiting the maximum output current of the converter. The maximum output current of the converter is actually located at the value Ipic (higher than Ilim), which is determined by a constant Ton. FIG. 5 shows a timing diagram of the operation of protection from overload. Further, the control circuit 207 is configured to open the first switch Qhs for a predetermined minimum period that allows the maximum frequency of converter operation to be limited during the transient phase.