SSZT123 October 2021 TMS320F2800137 , TMS320F280039 , TMS320F280039C , TMS320F280039C-Q1
Meghana Manavazhi
With the usage of servers and data centers growing globally, the need for stable and efficient power supplies has become an essential part of supporting the rise in power consumption. The utilization of power has been growing rapidly, with an increasing number of integrated central processing units, graphics processing units and accelerators needed to increase the calculation speeds of servers and data centers. Boosting the application benefits has spawned an evolution for power-supply units (PSUs) to deliver high power efficiency, fast transient response and high power density with larger power capacity.
Server PSUs with high power efficiency can lower the costs and environmental impact of operating data centers by reducing power waste and enabling the maximum transfer of power from the source to the load. This capability enables data centers to meet tightening efficiency standards such as 80 Plus, achieve higher-than-average titanium efficiency in a wide load range, and release less carbon dioxide into the environment.
In a server power application, having a fast transient response helps provide stable and reliable system operation under changing load and input transients. In addition, systems need to meet tighter transient response specifications of server power original equipment manufacturers: an 80% to 100% load jump at 2.5 to 5 A/µS. Figure 1 illustrates these parameters.
The growing power consumption of servers and data centers requires larger power capacity. Power technologies such as gallium nitride (GaN) are enabling smaller power supplies by allowing larger power capacity in a smaller space. Controlling the high switching frequency with a real-time microcontroller (MCU) is critical to achieving high power density in these systems and lowering the overall system bill of materials.
To achieve these benefits, server PSU manufacturers face several design challenges, such as
To meet the growing requirements of power efficiency and power density in server PSU systems, real-time MCUs need several key features, such as a low-latency signal chain, high pulse-width modulation (PWM) flexibility and resolution, high control-loop speeds and a high switching frequency. Figure 2 shows a sample PSU block diagram.
TMS320F280039C C2000™ real-time MCUs offer all of these traits while helping meet or reduce server PSU design budgets. They continue to improve integrated real-time signal chains (sensing, processing and control) through flexible and innovative capabilities. Figure 3 shows the F28003x family.
The F280039C MCU enables both high power efficiency and fast transient response times in server PSUs with its integrated analog components, including multiple 4-MSPS analog-to-digital converters with flexible start-of-conversion management, 11 effective number of bits and a post-processing block. The MCU also integrates fast analog comparators with optimized power-control features such a blanking, delayed trip, peak current-mode control and slope compensation for precise power conversion
Built on a 32-bit digital signal processor architecture combined with a control law accelerator, the F280039C offers over 240 MIPS of real-time performance, with features such as floating-point unit and trigonometric math unit to enable higher power density and high transient response with processing for complex time-critical calculations.
Enabling larger power capacities and maintaining synchronization across phases, even at high frequencies, is paramount in high-wattage server PSU systems. The F280039C offers 150-ps resolution PWM channels with features such as valley switching, delayed trip, dead-time adjustment and global reload that allow precise control of complex power topologies and control algorithms. The integrated configurable logic block further enhances PWM flexibility and enables seamless interfacing with GaN technology to enable high power density.
Apart from trends in power management and fast real-time control, several other requirements are gaining traction in server PSUs that F280039C MCUs can achieve:
The F280039C MCU expands on the C2000 MCU platform, offering integrated features that help you achieve advanced real-time control while reducing bill-of-materials costs. The F28003x MCU family complements the needs of wide bandgap technologies like GAN and SiC by unlocking their full potential to higher power efficiency and power density and faster response times. Easy-to-use software enables server PSU designers to accelerate development.
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