A voltage regulating circuit including a conversion circuit configured to convert a voltage pulse sequence into a filtered analog voltage, wherein the voltage pulse sequence represents a predefined operating limiting voltage, and a regulator configured to receive the filtered analog voltage as regulation variable and to regulate an output voltage of the voltage regulating circuit to a predefined desired voltage.

A low-temperature drift ultra-low-power linear regulator includes eight PMOS transistors, two resistors, two capacitors and three NMOS transistors. The eight PMOS transistors include PMOS transistor PM1 to PMOS transistor PM8. The two resistors include resistor R1 and resistor R2. The two capacitors include capacitor C1 and capacitor C2. The three NMOS transistors include NMOS transistor NM1, NMOS transistor NM2 and NMOS transistor NM3. From right to left, the linear regulator includes a PTAT voltage core starting circuit, a PTAT voltage core circuit, a negative temperature characteristic generating circuit and a driver stage closed-loop control circuit. PM5-PM8 form a feedback circuit. The feedback circuit clamps the current flowing through PM6 to be proportional to PM2 to obtain a temperature-stable output voltage, and can dynamically adjust the gate voltage of PM5 according to the change of load current to output different currents according to the load demand.

A power supply device having variable output voltage includes a controller, and a first power supply module and a second power supply module connected in parallel. The controller selectively outputs a first voltage control signal and a first switch control signal to the first power supply module, or outputs a second voltage control signal and a second switch control signal to the second power supply module according to a voltage requirement signal. An output power of the first power supply module has a first voltage value selected from a first voltage value set, an output power of the second power supply module has a second voltage value selected from a second voltage value set, and a minimum value of the first voltage value set is greater than a maximum value of the second voltage value set. Thus, more extensive voltage output capabilities are provided, and good power conversion efficiency is achieved at the same time.

A power supply device having variable output voltage includes a controller, and a first power supply module and a second power supply module connected in parallel. The controller selectively outputs a first voltage control signal and a first switch control signal to the first power supply module, or outputs a second voltage control signal and a second switch control signal to the second power supply module according to a voltage requirement signal. An output power of the first power supply module has a first voltage value selected from a first voltage value set, an output power of the second power supply module has a second voltage value selected from a second voltage value set, and a minimum value of the first voltage value set is greater than a maximum value of the second voltage value set. Thus, more extensive voltage output capabilities are provided, and good power conversion efficiency is achieved at the same time.

A converter assembly including a source connection system including a primary source connection, and a plurality of secondary source connections, a load connection system including a load connection, a secondary source bus bar system, a switch system including a plurality of switch units each connected electrically between a corresponding secondary source connection and the secondary source bus bar system, and at least one converter module including a DC link and a secondary source side converter. Each switch unit of the switch system includes a first switch and a second switch connected in parallel, wherein the first switch has a higher switching speed than the second switch, and the second switch has a lower conduction losses than the first switch.

A converter assembly including a source connection system including a primary source connection, and a plurality of secondary source connections, a load connection system including a load connection, a secondary source bus bar system, a switch system including a plurality of switch units each connected electrically between a corresponding secondary source connection and the secondary source bus bar system, and at least one converter module including a DC link and a secondary source side converter. Each switch unit of the switch system includes a first switch and a second switch connected in parallel, wherein the first switch has a higher switching speed than the second switch, and the second switch has a lower conduction losses than the first switch.

A power supply device having variable output voltage includes a controller, and a first power supply module and a second power supply module connected in parallel. The controller selectively outputs a first voltage control signal and a first switch control signal to the first power supply module, or outputs a second voltage control signal and a second switch control signal to the second power supply module according to a voltage requirement signal. An output power of the first power supply module has a first voltage value selected from a first voltage value set, an output power of the second power supply module has a second voltage value selected from a second voltage value set, and a minimum value of the first voltage value set is greater than a maximum value of the second voltage value set. Thus, more extensive voltage output capabilities are provided, and good power conversion efficiency is achieved at the same time.

A power supply device having variable output voltage includes a controller, and a first power supply module and a second power supply module connected in parallel. The controller selectively outputs a first voltage control signal and a first switch control signal to the first power supply module, or outputs a second voltage control signal and a second switch control signal to the second power supply module according to a voltage requirement signal. An output power of the first power supply module has a first voltage value selected from a first voltage value set, an output power of the second power supply module has a second voltage value selected from a second voltage value set, and a minimum value of the first voltage value set is greater than a maximum value of the second voltage value set. Thus, more extensive voltage output capabilities are provided, and good power conversion efficiency is achieved at the same time.

Examples relate to a buffered flipped voltage follower circuit arrangement, low dropout voltage regulators, a capacitive digital-to-analog converter, a transceiver for wireless communication, a mobile communication device, a base station transceiver, and to a method for forming a buffered flipped voltage follower circuit arrangement. The buffered flipped voltage follower circuit arrangement comprises a first transistor (M.sub.p) comprising a first terminal, a second terminal and a gate terminal. The buffered flipped voltage follower circuit arrangement comprises a second transistor (M.sub.c) comprising a first terminal, a second terminal and a gate terminal. The buffered flipped voltage follower circuit arrangement comprises a buffer circuit comprising an input terminal and an output terminal. The buffered flipped voltage follower circuit arrangement a feed-forward compensation circuit (−g.sub.mf) comprising an input terminal and an output terminal. The first terminal of the first transistor (M.sub.p) is coupled to a supply voltage of the flipped voltage follower circuit. The second terminal of the first transistor (M.sub.p) is coupled with the first terminal of the second transistor (M.sub.c) and with an output voltage terminal of the buffered flipped voltage follower circuit arrangement. The second terminal of the second transistor (Mc) is coupled with the input terminal of the buffer circuit and with the output terminal of the feed-forward compensation circuit (−g.sub.mf). The gate terminal of the first transistor (MP) is coupled with the output terminal of the buffer circuit and with the input terminal of the feed-forward compensation circuit (−g.sub.mf).

Examples relate to a buffered flipped voltage follower circuit arrangement, low dropout voltage regulators, a capacitive digital-to-analog converter, a transceiver for wireless communication, a mobile communication device, a base station transceiver, and to a method for forming a buffered flipped voltage follower circuit arrangement. The buffered flipped voltage follower circuit arrangement comprises a first transistor (M.sub.p) comprising a first terminal, a second terminal and a gate terminal. The buffered flipped voltage follower circuit arrangement comprises a second transistor (M.sub.c) comprising a first terminal, a second terminal and a gate terminal. The buffered flipped voltage follower circuit arrangement comprises a buffer circuit comprising an input terminal and an output terminal. The buffered flipped voltage follower circuit arrangement a feed-forward compensation circuit (−g.sub.mf) comprising an input terminal and an output terminal. The first terminal of the first transistor (M.sub.p) is coupled to a supply voltage of the flipped voltage follower circuit. The second terminal of the first transistor (M.sub.p) is coupled with the first terminal of the second transistor (M.sub.c) and with an output voltage terminal of the buffered flipped voltage follower circuit arrangement. The second terminal of the second transistor (Mc) is coupled with the input terminal of the buffer circuit and with the output terminal of the feed-forward compensation circuit (−g.sub.mf). The gate terminal of the first transistor (MP) is coupled with the output terminal of the buffer circuit and with the input terminal of the feed-forward compensation circuit (−g.sub.mf).