DC-DC converter apparatus and corresponding control method

The invention claimed is: 1 . A boost DC-DC converter apparatus, comprising: a boost inductor arranged in series with a supply voltage generator providing a supply voltage to said boost inductor; an output capacitor coupled to an output node in parallel with an output load; a switching network configured to selectively couple an output of the boost inductor to the output node under the control of a PWM driving signal; a control loop having an input coupled to receive the output voltage and an output providing said PWM driving signal, said control loop configured to produce an error signal as a function of a difference between the output voltage and a reference voltage and generate said PWM driving signal based on said error signal; a low pass filter circuit coupled to the control loop and configured to receive the PWM driving signal, the low pass filter circuit configured to apply low-pass filtering to the PWM driving signal and generate at least one filtered signal; wherein the control loop comprises at least one adder node configured to receive the at least one filtered signal from the low pass filter circuit and to add the at least one filtered signal to the error signal; wherein said PWM driving signal is generated as a function of a signal output from said at least one adder node. 2 . The boost DC-DC converter apparatus of claim 1 , wherein the control loop is a time-based control loop comprising: an integral control branch configured to convert said error signal into an integral control current signal from which a control signal is generated to control at least one current controlled oscillator to supply a first signal on which a switching frequency of the PWM driving signal depends, said first signal having a first phase depending on said integral control current signal; and a proportional branch configured to convert said error signal into a proportional control current signal from which a control signal is generated to control at least one delay line configured to delay said first signal by a second phase depending on said proportional control current signal to generate at least one time signal; a phase detector configured to receive said at least one time signal and output a switching voltage having a duty cycle that is a function of a phase of the at least one time signal; and a driver circuit configured to receive the switching voltage and control generation of the PWM driving signal. 3 . The boost DC-DC converter apparatus of claim 2 , wherein the low pass filter circuit comprises: an RC network configured to apply low-pass filtering to the PWM driving signal; and at least one transconductance amplifier configured to apply transconductance amplification to the low-pass filtered PWM driving signal to generate at least one filtered current signal to the time-based control loop; wherein the at least one adder node of the time-based control loop is configured to add the at least one filtered current signal to the integral control current signal and to the proportional control current signal; wherein a sum of the at least one filtered current signal and the proportional control current signal is used to obtain the control signal of the at least one delay line; and wherein a sum of the at least one filtered current signal of the integral control current signal is used to obtain the control signal of the at least one current controlled oscillator. 4 . The boost DC-DC converter apparatus of claim 1 , further comprising an offset compensation circuit coupled to the low pass filter circuit, the offset compensation circuit configured to apply offset compensation processing to the PWM signal, providing an offset compensated PWM signal to the low pass filter circuit. 5 . The boost DC-DC converter apparatus of claim 4 , wherein the offset compensation circuit comprises: a first resistive branch coupled to the supply voltage; a second resistive branch coupled to a setpoint reference node via a set of switches, the setpoint reference node configured to receive a setpoint reference voltage; where the first and second resistive branches are coupled at a common intermediate node providing a voltage indicative of a voltage ratio of the supply voltage and the setpoint reference voltage; a transconductance amplifier having a first input node coupled to the common intermediate node to receive the voltage ratio, a second input node coupled to a capacitive element referred to ground, and an output node configured to provide a current proportional to the voltage ratio at the first input node, wherein the second input node of the transconductance amplifier is coupled to the filter circuit and to a coupling circuit comprising a phase-frequency detector and a charge-pump circuit; and an offset calibration current controlled delay line coupled to the output node of the transconductance amplifier. 6 . The boost DC-DC converter apparatus of claim 4 , wherein the offset compensation circuit comprises: a first current generator coupled to a first switch via a first chopper switch that is driven to be made conductive or non-conductive via the PWM signal provided by the phase detector; a second current generator coupled to a second switch via a second chopper switch that is driven to be made conductive or non-conductive via the PWM signal provided by the phase detector; a third switch coupled to the output of the transconductance amplifier and to the second switch; wherein the first and the second current generators are configured to provide a reference current; and wherein the second switch and the second chopper switch have a common intermediate node coupled to the filter circuit. 7 . The boost DC-DC converter apparatus of claim 1 , wherein: the low pass filter circuit has a cut-off angular frequency ω FF ; and a transfer function G do,FF (S) between said PWM driving signal and the error signal produced as a function of a difference between the output voltage and the reference voltage is expressed as: G do , FF ( s ) = G do ( 0 ) ⁢ ( s 2 ω 0 ⁢ z 2 + s ω 0 ⁢ z ⁢ Q z