Integrated Inductive Switch-Mode Power Supply: Fondamentals on Feedback Control in Current Sliding Mode

Add to my library

D3184 V1 Article

Integrated Inductive Switch-Mode Power Supply: Fondamentals on Feedback Control in Current Sliding Mode

Author : Bruno ALLARD

Publication date: February 10, 2018 | Lire en français

Add to my library Add to my library

Logo Techniques de l'Ingenieur You do not have access to this resource.
Request your free trial access! Free trial

Already subscribed?

Overview

ABSTRACT

Low voltage allows the use of integrated semiconductor technologies and the deployment of advanced solutions with closed loop control. To ‘regulate’ converter output voltage against perturbations induced by dynamic load or input voltage variations, a ‘voltage regulator’ is needed. There are several feedback loop approaches. Modulation by pulse width at fixed frequency from voltage measurement offers limited dynamic performance. Nonlinear implementation, called sliding mode control, offers better results. This article describes this approach and sets out the principles of the hysteresis current loop and synchronization.

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHOR

  • Bruno ALLARD : University Professor - Electrical Engineering Department at INSA Lyon Laboratoire Ampère, UMR CNRS 5005, Villeurbanne, France

 INTRODUCTION

There are many strategies for controlling the power stage of a static switching converter. The focus here is restricted to non-isolated, non-resonant converters supplied with a DC input voltage, to provide a DC output voltage. Control of the output voltage must compensate for the impact of any variations, whether on the input voltage or on the output current. The [D3283] article deals with fixed-frequency voltage regulation, in voltage mode, i.e. only information on the variation in output voltage is used in the feedback loop. This involves measuring the output voltage and comparing this measurement with a reference voltage; often the reference voltage will be the value of the voltage to be obtained at output, or a fixed fraction thereof, or even a reference voltage at zero output current in the case of the Adaptive Voltage Positioning (AVP) of voltage regulators designed for processors. The comparison, if linear (analog), will produce an error voltage. This error voltage is used to drive the power stage through a modulation operation. The simplest form of modulation is pulse-width modulation (PWM). In other words, a fixed-frequency clock signal is transformed into a signal of the same frequency, but with modulated high and low durations. The duration of the high state becomes that of the energy draw from the input voltage, while the duration of the low state defines the duration of the discharge of the energy reservoir at the output, in the load. It is also possible, by the same means, to regulate the current in the load, if the current measurement produces an equivalent voltage (e.g. across a shunt). In a voltage down converter (or series chopper), if the output voltage drops, the current level in the inductor must be increased, and vice versa. Voltage information, the image of current, is used in a similar way to the direct measurement of output voltage in the case of a voltage converter (apart from a few details, linked to a concern for closed-loop stability). This fixed-frequency switching operation is of no particular interest when compared with output voltage control. Variable-frequency operation offers a more interesting degree of freedom. In this case, the comparison between the current image in the inductor and a reference value will be non-linear. The "discrete" nature of this type of control (current or voltage) immediately differentiates it from the fixed-frequency voltage control mentioned above.

Approaches can be combined to give additional transient performance to closed-loop control. For example, a first closed loop could control the current in the inductor (discrete character), and a second voltage control loop would produce the current reference to the first loop (linear character)....

You do not have access to this resource.
Logo Techniques de l'Ingenieur

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource. Click here to request your free trial access!

Already subscribed?


KEYWORDS

voltage controller   |   advanced control   |   current sliding mode   |   close-loop

Ongoing reading
Integrated Inductive Switch-Mode Power Supply: Fondamentals on Feedback Control in Current Sliding Mode

Article included in this offer

"Conversion of electrical energy"

( 278 articles )

Complete knowledge base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

View offer details

Dans les ressources documentaires

Principes de régulation en boucle fermée – approche en tension - Boucle fermée, régulateur de tension

L’échelle de tension faible permet l’utilisation de technologies intégrées de semi-conducteur d’une part ...

Commande numérique des convertisseurs d'électronique de puissance

Cet article fait le point sur trois grandes familles de nouvelles solutions numériques et leur contributi...

Applications des éléments piézoélectriques en électronique de puissance

Cet article s'intéresse aux applications de puissance des matériaux piézoélectriques. Ces matériaux sont ...

Tous les livres blancs
Article Une nouvelle source de lumière quantique
9 March 2016
Une nouvelle source de lumière quantique

Une nouvelle source de photons uniques ultra-brillante, 15 fois plus brillante que les sources usuelles et émettant des photons indiscernables à 99,5% les uns d...

Article Internet décentralisé : retour au Web 1.0 !
10 October 2018
Internet décentralisé : retour au Web 1.0 !

Désinformation, surveillance étatique, fuites de données... Le web actuel souffre de différents maux. Avec des réseaux décentralisés, les utilisateurs garderaie...

Toutes les actualités
Contact us