The implementation of a 2-core, multi-threaded itanium family processor

The design of the high end server processor code named Montecito incorporated several ambitious goals requiring innovation. The most obvious being the incorporation of two legacy cores on-die and at the same time reducing power by 23%. This is an effective 325% increase in MIPS per watt which necessitated a holistic focus on power reduction and management. The next challenge in the implementation was to ensure robust and high frequency circuit operation in the 90-nm process generation which brings with it higher leakage and greater variability. Achieving this goal required new methodologies for design, a greatly improved and tunable clock system and a better understanding of our power grid behavior all of which required new circuits and capabilities. The final aspect of circuit design improvement involved the I/O design for our legacy multi-drop system bus. To properly feed the two high frequency cores with memory bandwidth we needed to ensure frequency headroom in the operation of the bus. This was achieved through several innovations in controllability and tuning of the I/O buffers which are discussed as well.     

Power and temperature control on a 90-nm Itanium family processor

This paper describes the embedded feedback and control system on a 90-nm Itanium family processor, code-named Montecito, that maximizes performance while staying within a target power and temperature (PT) envelope. This system, referred to as Foxton Technology (FT), utilizes on-chip sensors and an embedded microcontroller to measure PT and modulate both voltage and frequency (VF) to optimize performance while meeting PT constraints. Changing both VF takes advantage of the cubic relationship of P/spl prop/CV/sup 2/F. We present measured results that show a 31% reduction in power for only a 10% drop in frequency. Montecito is able to implement FT using only 0.5% of the die area and 0.5% of the die power.     

Statistical clock skew modeling with data delay variations

Accurate clock skew budgets are important for microprocessor designers to avoid hold-time failures and to properly allocate resources when optimizing global and local paths. Many published clock skew budgets neglect voltage jitter and process variation, which are becoming dominant factors in otherwise balanced H-trees. However, worst-case process variation assumptions are severely pessimistic. This paper describes the major sources of clock skew in a microprocessor using a modified H-tree and applies the model to a second-generation Itanium-M processor family microprocessor currently under design. Monte Carlo simulation is used to develop statistical clock skew budgets for setup and hold time constraints in a four-level skew hierarchy. Voltage jitter through the phase locked loop (PLL) and clock buffers accounts for the majority of skew budgets. We show that taking into account the number of nearly critical paths between clocked elements at each level of the skew hierarchy and variations in the data delays of these paths reduces the difference between global and local skew budgets by more than a factor of two. Another insight is that data path delay variability limits the potential cycle-time benefits of active deskew circuits because the paths with the worst skew are unlikely to also be the paths with the longest data delays     

Comparison of adaptive body bias (ABB) and adaptive supply voltage (ASV) for improving delay and leakage under the presence of process variation

Process variations as a percentage of nominal delay and power consumption are becoming more and more severe with continuing scaling of VLSI technology. The worsening process variation causes increased variability in performance, power, and reliability of VLSI circuits. Thus, performance and power consumption targets obtained during the design phase of VLSI circuits may significantly deviate from that of actual silicon resulting in significant yield losses. Adaptive body bias (ABB) has been shown to be an effective method of postsilicon tuning to reduce variability under the presence of process variation. Post silicon tuning can also be accomplished by using adaptive supply voltage (ASV). This paper compares the effectiveness of ABB and ASV in reducing variability and improving performance and power, and thus, yield.     

A 90-nm variable frequency clock system for a power-managed itanium architecture processor

An Itanium Architecture microprocessor in 90-nm CMOS with 1.7B transistors implements a dynamically-variable-frequency clock system. Variable frequency clocks support a power management scheme which maximizes processor performance within a configured power envelope. Core supply voltage and clock frequency are modulated dynamically in order to remain within the power envelope. The Foxton controller and dynamically-variable clock system reside on die while the variable voltage regulator and power measurement resistors reside off chip. In addition, high-bandwidth frequency adjustment allows the clock period to adapt during on-die supply transients, allowing higher frequency processor operation during transients than possible with a single-frequency clock system.     

The implementation of the Itanium 2 microprocessor

This 64-b microprocessor is the second-generation design of the new Itanium architecture, termed explicitly parallel instruction computing (EPIC). The design seeks to extract maximum performance from EPIC by optimizing the memory system and execution resources for a combination of high bandwidth and low latency. This is achieved by tightly coupling microarchitecture choices to innovative circuit designs and the capabilities of the transistors and wires in the 0.18-/spl mu/m bulk Al metal process. The key features of this design are: a short eight-stage pipeline, 11 sustainable issue ports (six integer, four floating point, half-cycle access level-1 caches, 64-GB/s level-2 cache and 3-MB level-3 cache), all integrated on a 421 mm/sup 2/ die. The chip operates at over 1 GHz and is built on significant advances in CMOS circuits and methodologies. After providing an overview of the processor microarchitecture and design, this paper describes a few of these key enabling circuits and design techniques.