Voltage regulation of a series stacked system of digital loads by differential power processing

A modern high-end multi-core microprocessor has very stringent power supply requirements. It can draw hundreds of amperes of current at supply voltages as low as 0.8 V. As the supply voltages keep decreasing, the power delivery to meet the supply requirements is becoming increasingly difficult and inefficient. However, the presence of multiple cores in the microprocessor offers us a way to power it at a higher voltage by series-stacking the cores. Differential power processing has been shown to be an efficient way to series-stack server loads. In this work we study the dynamics of the element-to-element DPP topology implemented with bi-directional buck-boost converters. Some of its dynamic drawbacks are pointed out and a topological modification to counter those drawbacks is proposed. We then develop a linear control to regulate processor core voltages in a series stack of 4 cores. A hysteretic control to accommodate light load modes in the bi-directional regulating converters is also discussed. Both the linear and the hysteretic controller are implemented successfully in hardware and efficiency improvement due to light-load modes is demonstrated

Light-load power management in differential power processing systems

Series stacking is used as a means of implicitly raising DC bus voltages without additional power processing and has been explored widely in the context of photovoltaic sources and batteries in the past. More recently it has also been explored in the context of server loads and microprocessor cores. Supplying power at a higher voltage supports a reduction in conduction losses and reduces complexity in power supply design related to the high current at low voltage nature of microprocessor loads. However, series stacking of DC voltage domains forces the dc voltage domains to share the same currents. In the context of series stacked loads, this would lead to failure of voltage regulation of individual dc voltage domains. Additional power electronics, commonly referred to as differential power processing (DPP) units are required to perform this vital task. The idea is to let the DPP converters (which need to have bidirectional capability) process the difference between currents of adjacent voltage domains, so that the load voltages are regulated. Although series stacking and DPP has been explored in significant detail, the importance of light load efficiencies of these DPP converters has not been highlighted enough in the past. In this document we discuss the importance of light load control in common series stacked systems with DPP and propose a light load power management scheme for bidirectional buck-boost converters (which is the building block of most DPP converter topologies). Extending efficient operation load range of converters (to process higher power in rare heavily mismatched conditions and to maintain good light load efficiencies at the same time) with multiphase converters and asymmetric current sharing is also discussed in the context of DPP converters. We finally propose to build a series stacked system of low voltage loads and DPP regulators to demonstrate the advantages of series stacking as opposed to the conventional parallel connection

Design and Control of Power Converters 2019

In this book, 20 papers focused on different fields of power electronics are gathered. Approximately half of the papers are focused on different control issues and techniques, ranging from the computer-aided design of digital compensators to more specific approaches such as fuzzy or sliding control techniques. The rest of the papers are focused on the design of novel topologies. The fields in which these controls and topologies are applied are varied: MMCs, photovoltaic systems, supercapacitors and traction systems, LEDs, wireless power transfer, etc

Dsp-controlled multiphase hysteretic VRM with current sharing equalization

Many of the new high-speed high-integration density Integrated Circuits (ICs) and future generation of microprocessor powering requirements can be successfully achieved with voltage-mode hysteretic control applied to interleaved multiphase Point-of-Load (POL) DC-DC converters or Voltage Regulator Modules (VRMs). This is because of the several advantages that can be achieved by combining the advantages of hysteretic control and interleaving. However, there are several challenges in combining the two techniques, the most prominent being the current sharing and equalization between the interleaved phases. In this communication, we present a solution based on a real-time DSP controller. Challenges of the implementation will be discussed and experimental results obtained from a prototype will be presented

Dsp-Controlled Multiphase Hysteretic Vrm With Current Sharing Equalization

Many of the new high-speed high-integration density Integrated Circuits (ICs) and future generation of microprocessor powering requirements can be successfully achieved with voltage-mode hysteretic control applied to interleaved multiphase Point-of-Load (POL) DC-DC converters or Voltage Regulator Modules (VRMs). This is because of the several advantages that can be achieved by combining the advantages of hysteretic control and interleaving. However, there are several challenges in combining the two techniques, the most prominent being the current sharing and equalization between the interleaved phases. In this communication, we present a solution based on a real-time DSP controller. Challenges of the implementation will be discussed and experimental results obtained from a prototype will be presented. © World Scientific Publishing Company

DSP-controlled multiphase hysteretic VRM with current sharing equalization

Many of the new high-speed high-integration density Integrated Circuits (ICs) and future generation of microprocessor powering requirements can be successfully achieved with voltage-mode hysteretic control applied to interleaved multiphase Point-of-Load (POL) DC-DC converters or Voltage Regulator Modules (VRMs). This is because of the several advantages that can be achieved by combining the advantages of hysteretic control and interleaving. However, there are several challenges in combining the two techniques, the most prominent being the current sharing and equalization between the interleaved phases. In this communication, we present a solution based on a real-time DSP controller. Challenges of the implementation will be discussed and experimental results obtained from a prototype will be presented