Power density 

Achieve more power in smaller spaces, enhancing system functionality at reduced system costs

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What technologies are enabling greater density?

Board area and height are becoming limiting factors as power demands increase. Power designers must squeeze more circuitry into their applications to differentiate their products while also increasing efficiency and enhancing thermal performance. Higher power levels in smaller form factors are now possible using TI’s advanced process, packaging and circuit-design technologies.

Understanding the Trade-Offs and Technologies to Increase Power Density

Space is limited in power-supply designs, and engineers face constant pressure to do more with less. The need for improved power density is clear, but what limits designers from increasing power density today? In this paper, we examine the barriers in depth and provide technology examples to help you overcome them.

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Benefits of TI technologies for power density

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Smaller footprint, less heat

Save board space with high-performance device options that pair unique integration techniques and ultra-low RDSON, low-RSP FETs for smaller die sizes.

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Improved thermal performance

Remove heat from the package with advanced cooling technologies, including enhanced HotRod™ QFN packaging, power wafer chip-scale packaging (WCSP) and top-side cooling.

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Increased efficiency

Use smaller passives while switching at higher frequencies – without sacrificing efficiency – with multilevel converter topologies and advanced power-stage gate drivers.

Three ways to overcome thermal challenges

From circuit design to packaging R&D, thermally optimized system designs and more, TI is your partner in solving power density challenges. Learn more about our multi-faceted approach to making smaller, higher performance ICs a reality.
 

Featured power-density products

NEW Gallium nitride (GaN) power stages LMG2100R044 ACTIVE 100-V 4.4-mΩ half-bridge GaN FET with integrated driver and protection
NEW Isolated power modules (integrated transformer) UCC33420-Q1 ACTIVE Automotive, 5V/5V 1.5W 3kVrms isolated DC-DC module with integrated transformer
AC/DC & DC/DC converters (integrated FET) TPS62876-Q1 ACTIVE Automotive, 2.7V to 6V input, 25A stackable synchronous buck converter
High-side switches TPS274C65 ACTIVE 12-V to 36-V 65-mΩ four-channel high-side switch with SPI interface and integrated ADC
NEW Gallium nitride (GaN) power stages LMG3624 ACTIVE 650V 170mΩ GaN FET with integrated driver, protection and current sensing
NEW Isolated gate drivers UCC5880-Q1 ACTIVE Automotive, 20A, real-time variable IGBT/SiC MOSFET isolated gate driver with advanced protection

Featured reference designs for power density

Reference design
GaN-based, 6.6-kW, bidirectional, onboard charger reference design
The PMP22650 reference design is a 6.6-kW, bidirectional, onboard charger. The design employs a two-phase totem pole PFC and a full-bridge CLLLC converter with synchronous rectification. The CLLLC utilizes both frequency and phase modulation to regulate the output across the required regulation (...)
Reference design
High-power, high-performance automotive SiC traction inverter reference design

TIDM-02014 is a 800-V, 300kW SiC-based traction inverter system reference design developed by Texas Instruments and Wolfspeed provides a foundation for OEMs and design engineers to create high-performance, high-efficiency traction inverter systems and get to market faster. This solution (...)

Reference design
Variable-frequency, ZVS, 5-kW, GaN-based, two-phase totem-pole PFC reference design
This reference design is a high-density and high-efficiency 5-kW totem-pole power factor correction (PFC) design. The design uses a two-phase totem-pole PFC operating with variable frequency and zero voltage switching (ZVS). The control uses a new topology and improved triangular current mode (...)

Breaking down the fundamentals of power density

Every new technology advancement demands more power in smaller spaces. That’s the promise of power density – smaller packages, higher current, fewer trade-offs. See how we're driving greater density for the years to come.

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