LINEAR TECHNOLOGY AN119B-2 User Manual

Application Note 119B

April 2008

Powering Complex FPGA-Based Systems Using Highly
Integrated DC/DC µModule Regulator Systems

Part 2 of 2 Thermal Performance and Layout

Alan Chern and Afshin Odabaee

60W by Paralleling Four DC/DC μModule Regulators

In part one of this article, we discussed the circuit and
electrical performance of a compact and low profi le 48A,

1.5V DC/DC regulator solution for a four-FPGA design. The
new approach uses four DC/DC μModule
parallel (Figure 1) to increase output current while shar­ing the current equally among each device. This solution
relies on the accurate current sharing of these μModule
regulators to prevent hot-spots by dissipating the heat
evenly over a compact surface area. Each DC/DC μModule
regulator is a complete power supply with on-board inductor,
DC/DC controller, MOSFETs, compensation circuitry and
input/output bypass capacitors. It occupies only 15mm ×
15mm of board area and has a low profi le (height) of only

2.8mm. This low profi le allows air to fl ow smoothly over
the entire circuit. Moreover, this solution casts no thermal
shadow on its surrounding components, further assisting
in optimizing thermal performance of the entire system.

®

regulators in

Thermal Performance

Figure 2 is a thermal image of the board shown in Figure 1
with readings of the temperatures at specifi c locations.
Cursors 1 to 4 show an estimation of the surface tem­perature on each module. Cursors 5 to 7 indicate the
surface temperature of the PCB. Notice the difference in
temperature between the inner two regulators, cursors 1
and 2, and the outside, cursors 3 and 4. The LTM4601
μModule regulators placed on the outside have large planes
to the left and right promoting heat sinking to cool the
part down a few degrees. The inner two only have small
top and bottom planes to draw heat away, thus becoming
slightly warmer than the outside two.

Airfl ow also has a substantial effect on the thermal balance
of the system. Note the difference in temperature between
Figures 2 and 3. In Figure 3, a 200LFM airfl ow travels
evenly from the bottom to the top of the demo board,
causing a 20°C drop across the board compared to the
no airfl ow case in Figure 2.

L, LT, LTC, LTM, μModule, Linear Technology and the Linear logo are registered trademarks of
Linear Technology Corporation. All other trademarks are the property of their respective owners.

Figure 1. Four DC/DC μModule Regulator Systems Current Share to Regulate 1.5V at 48A With Only 2.8mm Profi le and 15mm × 15mm
of Board Area for Each Device. Each μModule Regulator Weighs Only 1.7g and Has an IC Form-Factor that Can Easily be Used With
Any Pick-and-Place Machine During Board Assembly

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AN119B-1

Application Note 119B

The direction of airfl ow is also important. In Figure 4 the
system is placed inside a 50°C ambient chamber with
airfl ow traveling from right to left, pushing the heat from
one μModule regulator to the next, creating a stacking
effect. The μModule device on the right, the closest to
the airfl ow source, is the coolest. The leftmost μModule
regulator has a slightly higher temperature because of
spillover heat from the other μModule regulators.

Heat transfer to the PCB also changes with airfl ow. In
Figure 2, heat transfers evenly to both left and right sides
of the PCB. In Figure 4, most of the heat moves to the
left side. Figure 5 shows an extreme case of heat stacking
from one μModule device to the next. Each of the four
μModule regulators is fi tted with a BGA heat sink and the
entire board is operated in a chamber with an ambient
temperature of 75°C.

Figure 2. Thermograph of 48A, 1.5V Circuit of Figure 1 Shows
Balanced Current Sharing Among Each DC/DC μModule
Regulator and Low Temperature Rise Even Without Airfl ow
(VIN = 20V to 1.5V

Figure 4. Thermograph of Four Parallel LTM4601 with 400LFM
Right-to-Left Airfl ow in 50°C Ambient Chamber (12VIN to 1V
at 40A)

OUT

at 40A)

OUT

Figure 3. Thermograph of Four Parallel LTM4601 with 200LFM
Bottom-to-Top Airfl ow (20VIN to 1.5V

Figure 5. Thermograph of Four Parallel LTM4601 With
BGA Heatsinks and 400LFM Right-to-Left Airfl ow in a 75°C
Ambient Chamber (12VIN to 1V

OUT

at 40A)

OUT

at 40A)

AN119B-2

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