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Infineon proposes a Quasi-Autonomous Gate Driver (QAGD) to manage an electrically actuated component, whether electromechanical, electromagnetic, or electrohydraulic. This paper examines some current control strategies that can be implemented within the QAGD, such as: Synchronous Sampling (SYSA), Hysteresis, Improved Synchronous Sampling-Hysteresis (ISSH), Suboscillation, Suboscillation with Back EMF Feedforward (SBEF) and Synchronous Control in Rotation Coordinates (SCRC). Analysis and simulation of these strategies indicate their advantages and disadvantages, which are then summarized in a comparison chart, from which the best solution for a given application can be determined. The QAGD IC proposed by Infineon adopts this solution by integrating the current controller and the driver unit for the MOSFETs in a single package. The inverter function can therefore be implemented using one QAGD and several MOSFETs, which greatly simplify the system and decrease the costs.

The objective of this SAE paper is to discuss a power stage partitioning which will provide a cost effective and flexible Infineon Technologies solution to control future E-Valve applications. To fulfil environmental demands, E-Valve applications will enable car manufacturers to: Dynamically reduce the number of working cylinders according to the drivers' torque requirements Have an efficient and variable control over the engine load in various conditions Dispense with throttles and exhaust recirculation valves The paper will describe: 1 The integration of the 4 MosFET and the future technology development required for the next system optimization. 2 Gate driver integration (3 different scenarios): Analog Interfacing between the μcontroller and the MosFETs with an integrated protection functionality (Scenario A).

The demands of the automotive market are decreasing the time-to-market required from the initial concept of new control systems to their implementation. The goal of automotive companies is to constantly reduce the development time to reap the full economic and strategic benefits of being quicker to market. The target is to reach a development time of less than 12 months for some applications. At the same time, the complexity of these new systems is growing almost exponentially. While new techniques like model-based control design with executable specifications, rapid control prototyping and hardware-in-the-loop simulation have helped significantly streamline the development process, the new strategies are still being transferred to the production target by hand. During an early project phase, automotive customers also need to explore different silicon architectures provided by semiconductor manufacturers to select the vendors who can offer the best solution at the lowest price.