Multi-Branch Current Sensing Based Single Current Sensor Technique for Power Electronic Converters

Cho, Younghoon

05 November 2012

A new concept of current sensor reduction technique called multi-branch current sensing technique (MCST) is proposed in this dissertation. In the proposed current sensing method, one more branch currents are simultaneously measured several times in a single switching cycle by using a single current sensor. After that, the current reconstruction algorithm is applied to obtain all phase currents information. Compared to traditional single current sensor techniques (SCSTs), the proposed method samples the output of the current sensor regularly, and the current sensing dead-zone is dramatically reduced. Since the current sampling is performed periodically, its implementation using a digital controller is extremely simple. Moreover, the periodical dead-zone and the dead-zone near the origin of the voltage vector space which have been a big problem in the existing methods can be completely eliminated. Accordingly, there is no need to have a complicated vector reconfiguration or current estimation algorithm. The proposed MCST also takes the advantages of a SCST such as reduced cost and elimination of the sensor gain discrepancy problem in the multiple current sensor method. The fundamental concept, implementation issues, and limitation of the proposed MCST are described based on three-phase systems first. After that, the proposed MCST is adopted to two-phase inverters and multi-phase dc-dc converters with little modifications. Computer simulations and hardware experiments have been conducted for a three-phase boost converter, a three-phase motor drive system, a two-phase two-leg inverter, a two-phase four-leg inverter with bipolar modulation, a two-phase four-leg inverter with unipolar modulation, and a four-phase dc-dc converter applications. From the simulations and the experimental results, the feasibilities of the proposed method mentioned above are fully verified. / Ph. D.

multi-branch current sensing technique

multi-phase converter

current feedback

three-phase inverter

two-phase inverter

single current sensor technique

Регулисани погон асинхроног мотора са минималним бројем сензора / Regulisani pogon asinhronog motora sa minimalnim brojem senzora / Vector-controlled induction motor drive with minimal number of sensors

Adžić Evgenije

14 February 2014

<p>У тези су предложена два унапређена алгоритма управљања<br />асинхроним мотором у условима када је број сензора који се користи у<br />погону минималан. Број сензора који се користи у повратној спрези<br />управљачког алгоритма сведен је на само један струјни сензор који<br />мери струју једносмерног међукола погонског инвертора. Предложене<br />методе елиминишу карактеристично изобличење реконструисаних<br />фазних струја и постижу бољи квалитет и перформансе управљања у<br />односу на конвенционалну методу. Сва аналитичка разматрања у тези<br />су праћена одговарајућим експерименталним резултатима, који<br />потврђују ефикасност предложених метода управљања.</p> / <p>U tezi su predložena dva unapređena algoritma upravljanja<br />asinhronim motorom u uslovima kada je broj senzora koji se koristi u<br />pogonu minimalan. Broj senzora koji se koristi u povratnoj sprezi<br />upravljačkog algoritma sveden je na samo jedan strujni senzor koji<br />meri struju jednosmernog međukola pogonskog invertora. Predložene<br />metode eliminišu karakteristično izobličenje rekonstruisanih<br />faznih struja i postižu bolji kvalitet i performanse upravljanja u<br />odnosu na konvencionalnu metodu. Sva analitička razmatranja u tezi<br />su praćena odgovarajućim eksperimentalnim rezultatima, koji<br />potvrđuju efikasnost predloženih metoda upravljanja.</p> / <p>This thesis proposes two improved and robust induction motor drive control<br />methods, in the case when there is a minimal number of sensors for<br />providing feedback signals. Number of used sensors is reduced to only one<br />current sensor measuring the inverter dc-link current. Proposed methods<br />cancels offset jitter-like waveform distortion present in the reconstructed<br />motor phase currents, and achieves higher quality and drive performance<br />regard to conventional current reconstruction mechanism. Effectivness of the<br />proposed methods are verified on developed HIL (hardware-in-the-loop)<br />platform and laboratory induction motor drive prototype.</p>