As the semiconductor industry traverses through the deep-submicron process nodes, each plateau along the way carries its own signature bugaboo arising from physical effects. At 180 nm, timing-closure issues got everyone's attention. At 130 nm, signal integrity was the topic of the day. At 90 and 65 nm, though, power integrity and leakage are weighing on designers' minds. We now pack so many active elements onto such a small slab of silicon that power density has reached near-critical mass. For example, according to Srikanth Jadcherla, founder and CTO of ArchPro Design Automation, a die measuring 1 by 1 cm with power consumption of 1 W dissipates the equivalent of 10 GW per square kilometer, or 25 GW per square mile.

Along with enormous increases in power density comes the physics of the submicron realm. With narrower feature sizes come thinner gate insulators, and that translates into leakage power. Leakage across gates is a condition in which the gate never shuts entirely off. Rather, it continues to consume power even though it's in a nominally passive state. At the 65-nm node, leakage can constitute more than 40% of the overall power consumption of a system-on-a-chip (SoC) or ASIC (Fig. 1).

Unfortunately, leakage has a symbiotic, and positively reinforcing, relationship with temperature. Leakage begets heat, which begets more leakage, which begets even more heat. And, in worse-case scenarios, thermal runaway can ensue, leading to potential fires and/or explosions in enduser systems.

Thus, heat is indeed an enemy that must be faced head-on. Fortunately, designers can turn to a number of tools and methodologies for prediction and management of thermal effects. In this article, we'll explore some of the thermal-analysis methods that help unearth problem areas. We'll also discuss some best practices in the thermal-management arena.

LEAKAGE IS A KEY
In addition to its exponential relationship with temperature, leakage is at the root of more subtle, yet no less pernicious, effects. Chief among these are problems brought on by electromigration, which are exacerbated by the higher current densities.

Then there's the broader issue of thermal variation across a given die's planar dimensions—even in the Z dimension between metal layers. Not only do disparities exist in temperature at a great many points on and within the die, but those variations are far from constant. As major functional blocks turn on and off, switching activity will have an ongoing effect on the die's thermal characteristics.

THE PERFECT STORM
There is, in fact, an interconnected maze of effects brought about by temperature variation that involves timing, signal integrity, and reliability (Fig. 2). As mentioned, temperature has a positive feedback loop with power and leakage. But it also affects timing by weakening the driving capability of devices. Higher temperatures mean an increase in the passive resistance of interconnects, which in turn increases delays.

The effect of temperature on IR drop and electromigration is accomplished primarily through Joule heating, or self-heating of the interconnects. This is another result of the increased resistance of the wires due to elevated temperatures. The circuit's electromigration lifetime degrades exponentially with rising temperatures. In IR-drop terms, that increased resistance on the power and ground grids leads to larger IR drops, meaning more power consumption.

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