electronica 2012 POWER


Managing power distribution in densely-populated PCBs


As electronic PCBs become more densely packed and supply rail voltages proliferate, delivering the right power to all on-board devices with optimal space and power efficiency becomes essential. Robert Gendron looks at how designers can achieve this through developments in power distribution architecture and device technology


A


s the electronics industry has developed, some inexorable trends have become apparent. Boards decrease in size and


become more densely populated. Supply voltages demanded by on-board IC devices such as CPUs, DSPs, FPGAs, logic and memory have proliferated and there is a tendency towards lower levels such as 1.2 V. Minimisation of power demand is paramount, partly for Green considerations but also to avoid problems of heating, reliability and operating costs arising from excess power dissipation. Design engineers today are aware that, because of these issues, using a centralised power supply is rarely an option. Delivering a multitude of low-voltage feeds across a PCB would be prohibitively inefficient both in terms of board space and, because of I”R losses, electrical power. Different distributed power architectures have


appeared over the years to address these problems. Their objective is always the same; to develop each low voltage close to where it is needed, at the point of load (POL), while providing regulation and isolation as well as conversion. The success and on-going development of these architectures is largely dependent on the devices used in their implementation. These have been generating new design opportunities as the latest semiconductor, transformer and other technologies become available.


The intermediate bus architecture (IBA)


overcomes these limitations by using a different approach. An intermediate bus converter device (IBC) converts the DPA’s high DC voltage of 48 V or higher down to an intermediate level of 8 - 12 V that is adequate to power a number of narrow range non-isolated point of load (niPOL) devices. The IBC also provides isolation. Each niPOL generates the desired regulated output voltage for its own local load. Because the niPOLs are smaller than isolated DC - DC converters, IBA architecture is lower cost and uses less board space that a DPA solution. However it is less power-efficient, because of multiple conversions with both the IBC and niPOLs in the power train. Some of the niPOLs’ size and efficiency advantages are lost. Advances in device technology mean that IBA compromises can be overcome, sometimes partially and sometimes entirely. Essentially a return to DPA architecture has become possible, using iPOL devices with packaging and footprints approaching those of niPOLs. These iPOLs offer a wide input voltage range, so they can be fed by high DC voltages routed across the PCB to minimise I”R losses. Like the original DC - DC converters, these iPOLs offer isolation, voltage conversion and regulation at the point of load, eliminating the need for an IBC device. To the extent that it’s available, new technology is allowing a revised, more efficient and more compact implementation of the original DPA architecture which, in turn, is an improvement on IBA.


One beneficiary of this approach would be an automated test equipment (ATE) system where isolation is a key


The first move away from a centralised design was into Distributed Power Architecture (DPA) where incoming AC is converted into a DC bus feeding independent, isolated DC - DC converters used to drive the output loads. Although this method generates higher overall efficiency due to single-stage conversion for each output rail, it results in higher costs and takes up significantly more board space. These problems become worse as the number of on- board IC devices and voltage rails grows.


18 CIE electronica 2012


requirement. This application could be satisfied efficiently using an iPOL providing isolation, conversion and regulation at the test head. Communications line cards typically also require galvanic isolation, which could now be provided by iPOLs instead of an IBC. These iPOL devices now encapsulate magnetics, power semiconductor ICs, MOSFETs and passive components inside a single miniature housing. Suppliers are calling them power-supplies-in-a-package, or PSiPs, if they


have an integrated inductor, or power-supplies- on-a-chip (PwrSOC) without an inductor. Although these devices represent progress towards ‘ideal’ iPOLs, design and construction of an iPOL with a niPOL-like form factor creates many challenges and added complexities. Their development requires attention to the controller technology, an isolated transformer integrated within the package, MOSFETs and packaging. Accomplishing such a task requires system- level understanding with the ability to optimise the balance between size, power density, packaging, thermal management and the integrated power-supply topology that works optimally with the semiconductor switching controller. This expertise typically requires a blend of traditional brick design and advanced IC design technologies. Traditional brick designs have reduced open-frame or brick-type supply footprints, but not many have achieved the


density and IC-like packaging required for an ideal iPOL. Packaging advances for iPOLs have lagged those of niPOLs. For example half-, quarter- and eighth-brick sizes have been cut to a sixteenth-brick form factor. Yet this is still two to three times larger than a high-performance semiconductor IC-like package used for niPOL devices. Meanwhile, at IC level, there is only limited evidence of integrated isolation transformers of any significant power. Yet iPOLs do exist and are improving continuously to deliver increasing performance and/or power density. Like niPOLs, iPOLs are expected to continue in their development until they are implemented in semiconductor packages, further increasing their penetration into power system designs. As this technology develops, designers are expected to take a mixed approach comprising DPA and IBA attributes and using IBCs, niPOLs and iPOLs in combinations optimised for their particular application. This will make the best use of the technology available at any point in time to achieve the greatest flexibility, power density and efficiency currently available.


Stand 560, Hall A6 Vicor Corporation | www.vicorpower.com


Robert Gendron is Vice President, Marketing & Business Development at Vicor Corporation.


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44  |  Page 45  |  Page 46  |  Page 47  |  Page 48  |  Page 49  |  Page 50  |  Page 51  |  Page 52  |  Page 53  |  Page 54  |  Page 55  |  Page 56  |  Page 57  |  Page 58  |  Page 59  |  Page 60  |  Page 61  |  Page 62  |  Page 63  |  Page 64  |  Page 65  |  Page 66  |  Page 67  |  Page 68