Abstract: A method for improved wireless energy transfer includes steering a first energy beam, having a fundamental frequency, towards an energizable device. The first energy beam is formed by a plurality of polarizers of a first power access point (PAP). A first polarity of the first energy beam is aligned at the energizable device to a second polarity of a second energy beam formed by a second PAP, physically separate from, and having a wireless connection to, the first PAP, by combining at each of the polarizers of the first PAP a respective first polarized signal with a respective second polarized signal. The respective second polarized signal is formed by rotating the respective first polarized signal. The second PAP receives a PAP signal via the wireless connection and locally generates the fundamental frequency from the PAP signal.

Abstract: An electric motor according to the present invention includes a stator and a rotor. The stator includes a stator iron core and a coil. The stator iron core includes a plurality of iron core divisions connected to form an annular shape. Each of iron core divisions includes yoke and a tooth. The plurality of iron core divisions engage with each other such that protrusion portion of one of each adjoining pair of the plurality of iron core divisions engages with recess portion of the other of the corresponding adjoining pair of the plurality of iron core divisions in a manner that protrusion portion and recess portion are rotatable. In this case, rotation center S of protrusion portion is positioned on a bisector of an angle formed by extended and crossed center lines of the teeth of respective iron core divisions of corresponding adjoining pair of the plurality of iron core divisions. An internal diameter side extension portion projects toward adjoining iron core division.

Abstract: A method of making a permanent magnet rotor includes interference fitting pressure tools into bores in a rotor core as to deform material of the rotor core outwardly to bias permanent magnets mounted thereon in a radially outward direction against a fixation sleeve.

Abstract: A rotor of a motor capable of improving durability of the motor by increasing a bonding force between a ring magnet and a resin. The rotor includes a ring magnet having an insertion hole passing through the center thereof, a shaft inserted into the insertion hole, and a resin that is disposed between the insertion hole and the shaft and fixes the ring magnet and the shaft. The resin extends to upper and lower surfaces of the ring magnet so as to cover at least parts of the upper and lower surfaces of the ring magnet.

Abstract: According to one embodiment, there is provided an armature winding for an electrical rotating machine. The armature winding includes a plurality of coil pieces partly housed in a plurality of winding slots formed in a stator core, each coil piece comprising a plurality of wire conductors which are formed to be transposed by being twisted, wherein at least some of coil-piece end portions protruding outward from side surfaces of the stator core are configured to have different wire conductor transposition angles according to an amount of impinging fluxes or an impinging flux density.

Abstract: A stator unit for including a plurality of coils includes a stator core configured to have the coils wound around the stator core; and a routing member including a plurality of groove configured to have wires routed in the groove, the wires extending from the coils.

Abstract: An actuator for a vehicle air-conditioning unit, has a housing, an output driven by a gear train, a motor driving the output via the gear train, a PCB connected to the motor for supplying power to the motor; and lead wires connected to the PCB via a direct connection connector to supply power to the PCB. Terminals of the connector are crimped to the lead wires and make direct mechanical contact with contact pads formed on the PCB.

Abstract: Brush holder support plate (1) for an electric engine comprises a central through-hole (2) for the engine manifold and guide elements (10) for receiving brush holders (20) in sliding connection on the plate. The plate allows the brush holder to be mounted on the plate, engaging same in the direction running from the edge (1e) of the plate towards the central through-hole (2). The plate comprises a non-return stop (11) for each brush holder (20) after the latter has been mounted in sliding connection on the plate, the stop being elastically retractable. The brush holders (20) have a base shaped so as to be received in sliding connection in the guide elements (10) of the plate (1). They have a recess in the base of same suitable for being engaged by the corresponding non-return stop (11) of the plate (1).

Abstract: An electromechanical actuating drive (1) having a servomotor (2) arranged so that the servomotor (2) can rotate about its longitudinal axis in a vehicle, and a cable harness (3) having first and second ends. A first end of the harness (3) is connected to the servomotor (2) and the harness (3) extends, in an elastically deformable arc, from the first end to the second end. The second end of the harness (3) is positionally fixed in the vehicle. The second end of the cable harness (3) is clamped in a securing and deflecting device at a transfer point (5).

Abstract: A digitally controlled motor device with storage (1) comprises a stator and a flywheel (10) having an axis of rotation and being rotatably mountable on a shaft (60) of a rotating machine and having at least a first set of magnetic coils (13) arranged thereon; an induction rotor (20) having an axis of rotation and being mountable on the shaft in magnetic communication with the first set of magnetic coils of the flywheel such that a change in magnetic flux at the first set of magnetic coils induces a current in the induction rotor. At least one set of second magnetic coils (12) is arranged on the stator in magnetic communication with the induction rotor (20).

Abstract: A actuator and a pump using the actuator are provided. The actuator is used to drive a pump body. The actuator includes a base, a transmission assembly and a motor received in the base. The motor includes a stator, a rotor, and a driving shaft. The driving shaft is connected to the transmission assembly. The base includes a mounting bracket. The mounting bracket is partly embedded in the motor. The actuator has good integrality and a compact structure.

Abstract: A generator set is disclosed. The generator set includes an engine and a flywheel coupled to the engine. The generator set further includes a generator having a housing and a hub portion configured to receive power from the engine. The generator set further includes a coupling member coupled to the flywheel and the hub portion within the housing of the generator. The coupling member includes an outer ring member disposed adjacent to the flywheel. The coupling member further includes an inner ring member disposed within the outer ring member. The coupling member further includes a plurality of blocks disposed within each of plurality of slots. The coupling member is disposed at an axial distance from an inner face of the housing. The housing of the generator includes one or more access openings to access the coupling member from outside the housing.

Abstract: A Perpetual Electricity Turbine Vortex Force Reactor is an apparatus for creating “green” electricity by tapping the full power potential of a recirculating liquid vortex of any size. This is done by redirecting the continuous explosion of the liquid escaping through the hole in the vortex chamber into a flywheel turbine attached to electrical generators. The liquid is then recirculated by a pump in a bottom liquid tank back up to the Vortex Chamber to create a self contained power system that does not pollute and is eligible for inclusion as an electrical power source under the net metering laws of many States, Florida in particular. Since the system is size independent very small single device powering reactors are possible as are enormous reactors that can power industrial size generators. Once the machines are in wide spread use the reactors will help to reduce America's carbon footprint by replacing the need for fossil fueled electric generators.

Abstract: A rotating electric machine includes a ring-shaped cover. The ring-shaped cover includes an outer peripheral portion, an inner peripheral portion, wall portions, an outer peripheral channel, an inner peripheral channel, and radial channels. A coolant supplied into the ring-shaped cover is to flow through the outer peripheral channel by gravity. The coolant is to flow through the inner peripheral channel by gravity. The radical channels include a first radial channel and a second radial channel. The coolant is to flow from the outer peripheral channel to the inner peripheral channel by gravity through the first radial channel. The coolant is to flow from the inner peripheral channel to the outer peripheral channel by gravity through the second radial channel. The coolant is to flow from the second radical channel by gravity through the outer peripheral channel.

Abstract: An electric machine for a vehicle comprises a housing, a rotor shaft, a first fan member, and a second fan member. The housing includes a first end portion having at least one air inlet opening and an opposite second end portion having at least one air outlet opening. The rotor shaft extends through at least one of the first end portion and the second end portion and is configured to rotate relative to the housing. The first fan member is located within the housing and is mounted on the rotor shaft. The second fan member is located outside of the housing and is mounted on the rotor shaft. Rotation of the rotor shaft causes each of the first and second fan members to generate an airflow from the at least one air inlet opening to the at least one air outlet opening.

Abstract: An electric machine may include a stator and a rotor that is rotatably mounted about an axis of rotation. The rotor has an internal rotor core provided with at least one electric coil winding. The rotor core and the coil winding are radially enclosed by an external rotor casing, the greater part of the perimeter of which is composed of a soft magnetic material.

Abstract: A motor includes a motor part and an amplifier configured to supply electric power to the motor part. The motor part includes a stator and a rotor. The amplifier includes a first frame constituting a housing of the amplifier and a second frame. The second frame is arranged on a first face located in a direction perpendicular to a rotation axis direction of the rotor at the first frame. At least one substrate housed in the first frame is attached to the second frame.

Abstract: A motor assembly and an integrated circuit for motor drive. The motor assembly includes a single-phase permanent-magnet synchronous motor capable of being powered by an AC power source and an integrated circuit, wherein the single-phase permanent-magnet synchronous motor comprises a stator and a permanent-magnet rotor capable of rotating relative to the stator, the stator comprises a stator iron core and a stator winding wound on the stator iron core, the integrated circuit comprises: a housing and enabling the single-phase permanent-magnet synchronous motor to be started along a fixed direction when the drive circuit is energized each time.

Abstract: A motor component and an integrated circuit for driving a motor are provided. The integrated circuit includes a housing, pins extended out from the housing, and a switch control circuit disposed on a semiconductor substrate. The semiconductor substrate and the switch control circuit are packaged in the housing. The switch control circuit is configured to generate a control signal for controlling a bidirectional AC switch to be switched on or switched off, based on a magnetic field polarity of a rotor of the motor, to control an energized mode for the motor.

Abstract: A two-pole brush-commutated DC electric motor with a stator and a rotor with a hollow-cylindrical ironless winding having n coil segments and a commutator having n commutator segments. Each coil segment being electrically connected to two adjacent commutator segments. An axis of gravity intersects the rotor axis perpendicularly and passes through the center of gravity of a coil segment or a center line of the coil segment that passes through the center of gravity and the rotor axis spanning a coil plane that defines the angular position of the associated coil segment. Two brush contact surfaces of the commutator segments are electrically connected to this coil segment have a distance bisector intersecting the rotor axis perpendicularly. The distance bisector and the rotor axis span a commutator plane which defines the angular position of the associated commutator segments.

Abstract: A motor driving assembly includes a motor. The motor includes an outer housing, and a rotor and a brush holder received in the outer housing. The rotor includes a rotary shaft extending out of the outer housing. A commutator is fixed on a shaft portion of the rotary shaft within the outer housing. Brushes for contacting the commutator are disposed on the brush holder. A visible identification mark fixed relative to the rotary shaft is disposed outside the outer housing of the motor, such that a relative position between the brushes and the commutator in a rotational direction of the rotary shaft is identifiable by reference to a position of the visible identification mark relative to the outer housing in the rotational direction of the rotary shaft. As such, the commutator can be prevented from stalling at a position where arcing noise may be easily generated.

Abstract: A brushed motor includes a rotation shaft, a commutator including a plurality of segments separated by a plurality of undercuts arranged at unequal intervals, an armature, a plurality of permanent magnets, a voltage equalizing line, a positive electrode brush, and a negative electrode brush. When Pz is the number of the permanent magnets and N is the number of the segments, a relationship of N=Pz(K?0.5) is satisfied. Pz is an even number that is greater than or equal to four. K is a constant and is a natural number that is greater than or equal to two. The plurality of undercuts includes at least one set of undercuts arranged at an undercut interval that differs from a reference angle ?z. The reference angle ?z is specified by a relational expression of ?z=(360 degrees/Pz)±(360 degrees/2N).

Abstract: A brushless motor comprising: a rotor; a stator core disposed at a radial direction outside of the rotor, and a stator case. The stator core includes an outer ring shaped section, teeth sections projecting out from the outer ring shaped section toward a radial direction inside, and an inner ring shaped section extending from end portions of the teeth sections. Protruding portions are formed at the outer ring shaped section so as to project toward a radial direction outside and so as to be disposed at even intervals around a circumferential direction of the outer ring shaped section. The stator case is integrated together with the stator core by a plurality of plastic deformation portions formed at an outer peripheral portion of the stator case at locations facing towards the protruding portions, and the plastic deformation portions are disposed at even intervals along a circumferential direction of the stator case.

Abstract: The present disclosure relates to motors in general and, specifically relates to methods for producing a rotor for a permanently excited synchronous motor. A method may include: arranging a plurality of permanent magnets in a spoke-shaped pattern; and disposing a number of sheet metal elements between the respective permanent magnets. The respective sheet metal elements may be arranged one above the other and connected to one another. The respective sheet metal elements may include sections of soft-iron cores, a ring in the center of the rotor, and thin connecting pieces that connect the soft-iron core sections to the ring.

Abstract: A single phase permanent magnet brushless motor includes a stator and a rotor. The stator includes an outer housing, a stator core mounted in the outer housing, and windings wound around the stator core. The stator core includes a yoke and a plurality of poles extending inwardly from the yoke. The yoke is fixed to the outer housing by welding. Reliability of the present motor is enhanced.

Abstract: A rotating electric machine includes: a stator core having a plurality of slots aligned along a circumferential direction; a stator having a stator coil with an enamel coating inserted into the slots of the stator core; and a rotor rotatably arranged over the stator core through a given gap. The stator coil includes: main coils of a plurality of phases in which a plurality of segment coils each having a rectangular cross-section wire formed into a substantially U-shaped wire in advance is connected to each other; a first sub-coil having a lead wire led from the slots and attached with an AC terminal, and connected to one end of the respective main coils; and a second sub-coil having a neutral wire led from the slots, and connected to the other end of the respective main coils. The lead wire and the neutral wire are each formed of a wire with a bend structure having a plurality of straights and bends.

Abstract: A vibration motor includes a base portion, a magnet portion, an annular vibrating portion including a coil portion, and a mass portion, the vibrating portion being arranged around the magnet portion; a cover portion fixed to the base portion, and arranged to cover upper and lateral sides of the vibrating portion; and an annular elastic member arranged between the cover portion and the vibrating portion, and joined to both the upper portion of the cover portion and the vibrating portion. An inner edge portion of the elastic member is arranged radially inward of an inner circumferential edge of the mass portion. The inner edge portion of the elastic member includes a positioning portion defined therein. An outer surface of the upper portion of the cover portion includes a joint portion indicating a position at which the cover portion and the elastic member are joined to each other.

Abstract: The vibration electricity generation device comprises a fixed unit and a movable unit supported on the fixed unit via a coil spring. The movable unit is configured to vibrate against resilient force of the coil spring thereby generating induced electromotive force. The coil spring is coupled to the movable unit in a position apart from the center position of the movable unit with respect to the vibration direction toward the opposite side of the position where the coil spring is coupled to the fixed unit. Even in the case the vibration electricity generation device is reduced in size with respect to the vibration direction, the length of the coil spring can be extended, thereby enhancing selection freedom of vibration frequency.

Abstract: A stepper motor has a stator winding assembly with a permanent ring magnet located radially outside of electromagnetic windings for the stator poles. The permanent ring magnet remotely magnetizes a rotor seated by bearings on an axial shaft so as to rotate within the stator winding assembly, thereby freeing up space within the rotor for an internal damper. The rotor has a cylindrical damping weight enclosed within, but not fixed to, the rotor. The weight ideally has a rotational moment of inertia that substantially matches that of the rotor. The weight is elastically coupled to the rotor by a viscous material contained in the rotor and filling the space between the weight and the rotor and between the weight and the axial shaft. The viscosity of this material is selected such that motion of the weight is delayed, preferably so as to be substantially 180° out-of-phase with, but at the same frequency as, the stepping rotation of the rotor.

Abstract: A drive unit (8) for driving a tool. The drive unit (8) has at least one first drive module (18) comprising a motor (12) and a wheel (32) driven in a rotary manner around an axis (16) by the drive module (18). The drive module (18) comprises a magnetic ring (22) surrounding the wheel (32), with which the wheel (32) is connected in a magnetically force-transmitting manner and with which the motor (12) is connected in a mechanically force-transmitting manner.

Abstract: A method and a device provide intrinsically safe redundant current supply of field devices with a common current-limiting resistor in the mesh of the field device, wherein the field device is connected via a connection line to field-device connection terminals of the current supply device consisting of at least two current supply units. The output voltage and/or the output current of each current supply unit is reduced as a function of the voltage across the field-device connection terminals.

Abstract: An overvoltage protection circuit and a method for protecting against an output from a power supply reaching overvoltage levels is provided. The overvoltage protection provides two operational modes for the power supply. In both modes, the overvoltage protection monitors the output voltage of the power supply and disables it if the output voltage reaches a threshold indicating an overvoltage event. In normal operation, this threshold is set to a level that is higher than a nominal safety threshold defined for the power supply whereas in reduced operation, this threshold is set to a value lower than the safety threshold. When an overvoltage event is detected in normal operation, the overvoltage protection transitions the power supply into the reduced operational mode before reactivating it. The power supply may be reactivated, produce an overvoltage event, and be deactivated multiple times in the reduced operational mode.

Abstract: The present disclosure relates generally to a power source, a clamping device in electrical communication with the power source, wherein the clamping device is configured to redistribute a current generated by the power source, and a load in electrical communication with the clamping device and the power source.

Abstract: The present disclosure provides systems and related methods for reducing noise and interference in communications between an external device and implantable medical devices. The external device comprises an isolated switching power supply that includes a transformer separating a non-isolated side from an isolated side of the power supply. The transformer includes a primary winding on the non-isolated side, the primary winding extending between a primary winding upper end and a primary winding lower end, and a secondary winding on the isolated side, the secondary winding extending between a secondary winding upper end and a secondary winding lower end. The power supply further includes a high-frequency switch configured to selectively connect and disconnect the primary winding lower end to a ground, wherein the primary winding is electrically coupled to a supply voltage at an intermediate point between the primary winding upper end and the primary winding lower end.

Abstract: A charge pump circuit is coupled between a positive supply node and a ground node. The charge pump circuit operates in response to clock signals output from a clock generator to produce a negative voltage at a negative voltage output node. A soft-start circuit for the charge pump circuit includes a comparison circuit configured to compare a varying intermediate voltage sensed between a rising supply voltage and the negative voltage to a ramp voltage during a start-up period of the charge pump circuit. The clock generator is selectively enabled to generate the clock signals in response to the comparison to provide for pulse-skipping.

Abstract: A charge pump includes a current source circuit, a current sink circuit and a switch circuit. The switch circuit is coupled between the current source circuit and the current sink circuit, and is arranged for generating a first current at a first output terminal and generating a second current at a second output terminal according to a first control signal and a second control signal, wherein each of the first current and the second current is generated from the current source circuit.

Abstract: A first switching element and a gate of a voltage-driven switching element are connected by a gate turn-on wiring through a first resistor. The gate of the voltage-driven switching element and a second switching element are connected by a gate turn-off wiring through a second resistor. A charge pump unit has a first capacitor, and a second capacitor configured to output a negative voltage. A resistor unit is arranged in at least one of a first wiring configured to connect the gate turn-on wiring and the first capacitor and a second wiring configured to connect the gate turn-off wiring and the first capacitor, and is configured to charge the first capacitor through the first wiring when the first switching element is turned on and to discharge the first capacitor through the second wiring when the second switching element is turned on.

Abstract: A charge pump circuit suitable for low input voltages is presented. The charge pump circuit has a first clock signal generator, a second clock signal generator and n voltage doubler circuits. The voltage doubler has an input, an output, a first capacitor connected to the first clock signal generator, a second capacitor connected to the second clock signal generator, a first NMOST having the source connected to the input and the drain connected to the first capacitor, a second NMOST having the connected to the source of the first NMOST and the drain connected to second capacitor, a first PMOST having the drain connected to the first capacitor and the source connected to the output, a second PMOST having the source connected to the source of the first PMOST and the drain connected to the second capacitor.

Abstract: A power supply device includes a boost convertor configured to perform a boost-up operation to boost a voltage supplied from an input terminal, a connection-assist diode connected in parallel to the boost convertor between the input terminal and an output terminal, and a switching element connected in parallel to the boost convertor and the connection-assist diode between the input terminal and the output terminal. A controller instructs the switching element to open and instructs the boost convertor to perform a boost-up operation for boosting the voltage at the input terminal during a boost-up period. The controller instructs the boost convertor to stop the boost-up operation when the boost-up period elapses. The controller then instructs the switching element to close the switching element. The controller then determines a state of the switching element based on a voltage at the output terminal detected.

Abstract: A switching power supply apparatus includes a step-down converter that steps down an input current by turning on/off switching elements, a switching element electrically connected between the step-down converter and voltage outputs, and a microcontroller. An input-side resistor voltage dividing circuit and an output-side resistor voltage dividing circuit including elements with the same or similar specifications are electrically connected to the input and output of the switching element, respectively. The microcontroller stores coefficients of an expression which have been externally calculated according to a voltage detected by the output-side resistor voltage dividing circuit and a voltage detected at the voltage output portions. The microcontroller corrects a measurement value of an intermediate bus voltage detected by the input-side resistor voltage dividing circuit according to an expression and the stored coefficients.

Abstract: According to an embodiment, a method of operating a switching power supply includes applying a periodic switching signal to a first switch that is coupled to an output node, detecting an offset delay between applying the periodic switching signal and a change in voltage of the output node, calculating a corrected midpoint of a half phase of the periodic switching signal based on the offset delay, generating a sampling pulse based on the corrected midpoint, and sampling a current at the output node according to the sampling pulse.

Abstract: Example embodiments of the systems and methods of non-invasive continuous adaptive tuning of digitally controlled switched mode power supply based on measured dynamic response disclosed herein rely on time domain measurements for the tuning rather than on frequency response to automatically tune the system for stability and good dynamic performance. In particular, an algorithm directly measures overshoot and settling time to transients. Using this information, the algorithm minimizes both overshoot/undershoot and settling time by adjusting the parameters of a digital compensator. Since time domain measurements are directly used, the implementation does not require an additional perturbation in the system that otherwise would be necessary.

Abstract: A first conversion circuit switches a magnitude of a voltage generated between a first output point and a reference potential point in three stages. The second conversion circuit switches a magnitude of a voltage generated between the reference potential point and a second output point in three stages. The third conversion circuit includes first to fourth switches in a full bridge configuration and converts a voltage generated between the first output point and the second output point into an alternate current voltage and outputs the alternate current voltage. The third conversion circuit forms a current path including inductors between the first output point and the second output point during a start time period from a start of supplying power from a direct current power supply until a first capacitor and a second capacitor are charged to a specified voltage.

Abstract: A voltage or current regulated power converter is presented. The power converter is configured to derive electrical power at an output voltage Vout at an output of the power converter from electrical power at an input voltage Vin at an input of the power converter, wherein the output voltage Vout is greater than or equal to the input voltage Vin. The power converter comprises an inductor, a plurality of capacitors and a plurality of switches. The input and output unit are coupled via an intermediate point, wherein the output unit comprises a first output or second output arrangement, and wherein the input unit comprises a first input or a second input arrangement. The power converter comprises a controller configured to control the plurality of switches such that a commutation cycle of the power converter comprises a plurality of different operation phases.

Abstract: A regulating power converter has a transformer, a charging circuit and a discharging circuit connected with each other. The charging circuit charges said transformer whereby the transformer generates a secondary voltage. The discharging circuit discharges the secondary voltage to generate an output voltage. The charging circuit retrieves time information from the secondary voltage through the transformer. The charging circuit drives the transformer to regulate the output voltage according to the time information.

Abstract: A switching power supply device includes an output voltage detection unit that outputs an output voltage detection value. The control circuit includes: a target voltage generation unit that generates an output voltage setting value; an A/D conversion unit that A/D converts an error between the output voltage setting value and the output voltage detection value; a digital compensation unit that computes an amount of control based on an output signal of the A/D conversion unit; and a PWM signal generation unit that generates a PWM signal for the switching element based on the amount of control. The target voltage generation unit detects a standby state based on the output voltage detection value, the output signals of the A/D conversion unit and the digital compensation unit, and in the standby state, switches the output voltage setting value to a second value lower than a value for another state.

Abstract: A switching power converter is provided that extrapolates from a reference voltage during dead periods of a rectified input voltage as determined from a comparison of an Isense voltage to a current threshold.

Abstract: A switching power-supply device includes an input power detecting part that finds a DC input power from a detected DC input voltage and a detected DC input current, and an operation mode setting part that sets a burst mode operation or a continuous mode operation based on the DC power detected by the input power detecting part. The operation mode setting part also may set a ratio of a switching active period Tact, in which the main switching element is caused to perform switching operations, to a switching stop period Tstop, in which the switching operations are stopped, in the case of the burst mode operation in accordance with the detected input power.

Abstract: A symmetry control circuit for a trailing edge phase control dimmer circuit for controlling alternating current (AC) power to a load, the symmetry control circuit including: a bias signal generator circuit configured to monitor non-conduction periods of each half cycle of said AC power for an elapsed duration of the non-conduction periods, and generate a bias signal voltage based on the elapsed duration, whereby an amplitude of the bias signal voltage is proportional to the elapsed duration of the non-conduction periods; and a bias signal converter circuit configured to convert the bias signal voltage to a bias signal current, wherein the bias signal current is added to a reference current of a conduction period timing circuit configured to determine said conduction periods, and wherein the conduction period timing circuit is configured to alter one of the conduction periods immediately following one of the non-conduction periods based on the bias signal current when added to the reference current to compensa

Abstract: Methods and power conversion systems in which a capacitor degradation detection system includes an adjustable gain amplifier circuit is calibrated by automatic adjustment of at least one amplifier gain to accommodate current and voltage levels of a particular filter circuit in a first mode. Capacitance values of filter capacitors are calculated according to amplified current signals and compared with an acceptable tolerance range to selectively identify a filter capacitor fault or to store calculated capacitance values as base values in an electronic memory in the first mode. During operation in a second mode with the rectifier and inverter on, the adjusted amplifier gain is used to amplify current sensor signals and/or voltage signals, and capacitance values of the filter capacitors are used to selectively identify capacitor degradation.