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Nexperia announced a significant raising of the bar in semiconductor engineer design support with the release of next-generation interactive datasheets to accompany its Power MOSFETs. By manipulating interactive sliders within the datasheets, users can manually adjust the voltage, current, temperature and other conditions for their circuit application and watch how the operating point of a device dynamically responds to these changes.
These interactive datasheets effectively offer a type of graphical user interface to a circuit simulator, using Nexperia’s advanced electrothermal models to calculate the operating point of a device. In addition, they allow engineers to visualize immediately the interaction between parameters such as gate voltage, drain current, RDS(on) and temperature. Their collective contribution to the device behavior is then displayed dynamically in tables or graphs. As a result, Nexperia’s interactive datasheets can significantly increase productivity by eliminating the time needed for an engineer to perform manual calculations or set up and debug a circuit simulation.
The datasheet is commonly the first port of call when a design engineer is looking to select a device for an application. However, while they contain a wealth of information, including the minimum, maximum and typical specifications across dozens of device parameters, it is often difficult to determine how these are interrelated. Consequently, engineers must perform time-consuming manual calculations or set up a circuit simulator using models provided by the manufacturer (assuming these are available) to thoroughly investigate a device’s behavior. Even then, many manufacturers’ simulation models do not show the effect of temperature changes on device behavior. The new interactive datasheets from Nexperia support engineers by showing real-time interaction across different parameters as they are manually changed with the easy-to-use datasheet sliders.
Chris Boyce, Senior Director of Nexperia’s Power MOSFET business adds, “Whether you are a Design Engineer looking to see how a device will perform at elevated temperature, or a Component Engineer trying to compare devices under different test conditions, our new interactive datasheets are designed to make your life easier.”
The technology powering these datasheets is the same as that used in Nexperia’s hugely successful precision electrothermal MOSFET models, which demonstrate how the behaviour of discrete MOSFETs changes with temperature. The new interactive datasheets are offered in addition to the traditional static datasheets and operate in any standard web browser without the requirement of additional software for device simulation.
With the initial version currently under patent application, Nexperia will be reaching out to its global community of customer engineers to evaluate how interactive datasheets are used in real-time in order to broaden the functionality of future versions.
More than 200 interactive datasheets are already available, covering the devices in Nexperia’s latest generations of Automotive and Industrial Power MOSFETs. Over time, the Company plans to make them available for its entire portfolio of discrete MOSFETs and other devices. Try a live interactive datasheet in action at nexperia.com/interactive-datasheet
Original – Nexperia
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Nexperia introduced a 650 V Silicon Carbide (SiC) Schottky diode designed for power applications which require ultra-high performance, low loss, and high efficiency. The 10 A, 650 V SiC Schottky diode is an industrial-grade part that addresses the challenges of demanding high voltage and high current applications. These include switched-mode power supplies, AC-DC and DC-DC converters, battery-charging infrastructure, uninterruptible power supplies and photovoltaic inverters and allow for more sustainable operations. Data centers, for example, equipped with power supplies designed using Nexperia’s PSC1065K SiC Schottky diode will be better placed to meet rigorous energy efficiency standards than those using solely silicon-based solutions.
The PSC1065K delivers leading-edge performance with temperature-independent capacitive switching and zero recovery behavior culminating in an outstanding figure-of-merit (QC x VF). Its excellent switching performance is almost entirely independent of current and switching speed variations. The merged PiN Schottky (MPS) structure of the PSC1065K provides additional benefits, such as outstanding robustness against surge currents that eliminates the need for additional protection circuitry. These features significantly reduce system complexity and enable hardware designers to achieve higher efficiency with smaller form factors in rugged high-power applications. Designers can be further reassured by Nexperia’s proven reputation as a supplier of high-quality products in a range of semiconductor technologies.
This SiC Schottky diode is encapsulated in a Real-2-Pin (R2P) TO-220-2 through-hole power plastic package. Additional package options include the surface mount (DPAK R2P and D2PAK R2P) and through-hole (TO-247-2) with a real 2-pin configuration that enhances reliability in high-voltage applications at temperatures up to 175 °C.
Katrin Feurle, Senior Director of the Product Group SiC at Nexperia, adds: “We are proud to offer a high-performance SiC Schottky diode that ranks among the top tier of currently available solutions. In an increasingly energy-conscious world, we are bringing greater choice and availability to the market as demand for high-volume, high-efficiency applications increases significantly.”
Nexperia plans to continuously augment its portfolio of SiC diodes by including automotive-grade parts that operate at 650 V and 1200 V voltages with currents in the 6-20 A range. Samples and production quantities of the new SiC diodes are available now.
Original – Nexperia
