Design Note 1038: 42V High Power Density Buck Regulators in a Tiny QFN Package


Power dissipation is a significant problem facing the designers of DC/DC converters in industrial and automotive applications, where high currents are required, but space is limited. It is possible to produce a highly efficient regulator from high performance discrete components, but expense and solution footprint make this approach prohibitive. The LT8612/LT8613 high efficiency buck regulators integrate all the necessary components into a single IC, significantly reducing the DC/DC converter size, even when faced with high step-down ratios. These devices can also be paralleled to increase the output current capability and spread the load and heat.

Other desirable features included in these regulators are ultralow quiescent current to maximize battery life, and high switching frequency to minimize solution size and avoid noise-sensitive frequency bands.

High Efficient 42V, 6A Regulators in 3mm × 6mm Package

The LT8612/LT8613 is 42V, 6A step-down monolithic regulator. The low power dissipation of the integrated high efficiency power switches allows these switches, the boost diode, internal compensation and all necessary circuitry to be encapsulated in a tiny 3mm × 6mm QFN package without overheating. Figure 1 shows a typical 5V/30W LT8612 converter; its efficiency and power loss are demonstrated in Figure 2. Even with an input voltage of 24V, the LT8612 can produce a 30W output with no more than 50°C temperature rise. At the other end of the load spectrum, the LT8612/LT8613 uses low ripple Burst Mode® operation to enhance efficiency in ultralow load situations.

Figure 1. A 5V/30W Step-Down Converter Using the LT8612
Figure 2. Efficiency and Power Loss of the 5V/30WLT8612 Step-Down Converter in Figure 1.

The minimum on-times of LT8612/LT8613 are as low as 40ns, allowing for high VIN/VOUT ratios even at high switching frequencies. High switching frequencies, up to 2.2MHz, minimize the size and value of the power inductor and output capacitor. Furthermore, the inductor can be confidently sized based on the output load requirement—no need to use a larger inductor to provide design overhead—a result of the devices high speed peak-current mode architecture and robust switch design.

Multiphase Design to Increase Output Current Capability

Loads more than 6A are not uncommon in automotive and industrial applications. For these relatively high current conditions, a multiphase design can extend the output capabilities of the LT8612/LT8613 regulator. The LT8613 has a built-in rail-to-rail current sense amplifier with monitor and control pins, enabling accurate input or output average current regulation. This current loop modulates the internal switch current limit such that the voltage across the ISP/ISN pins does not exceed the voltage set by the ICTRL pin. Another IMON pin is used to monitor the average current that is measured through the ISP/ISN pins. This current control feature makes accurate current sharing among several LT8613s possible without any additional control circuitry.

Figure 3 shows three LT8613s paralleled for up to 16A output. The top LT8613 is the master regulator with its output voltage set to 4V, while the other two LT8613s are slave regulators with their output voltages set a little higher than 4V.

Figure 3. schematics of 3-Phase LT8613 Design Delivering 16A at 4VouT

In order to share current among the three LT8613 regulators, the IMON pin of the master LT8613 is connected to the ICTRL pins of the slave LT8613s. The three LT8613 regulators are synchronized by the 3-phase 700kHz clock signals (120° phase shift) generated from the LTC6909 oscillator. Figure 4 shows a thermal image of this 3-phase LT8613 design. The similarity in temperatures of the LT8613s indicates even current sharing among the three phases. The efficiency of this design is shown in Figure 5.

Figure 4. Thermal Image of 3-Phase LT8613 Design Shows Similar Temperatures
Figure 5. Typical Efficiency of 3-Phase LT8613Design Shown in Figure 3

If it is desirable to weight the current sharing among the phases—that is to unbalance the current sharing—simply adjust the values of the sense resistors across ISP and ISN pins.


The LT8612 and LT8613 are fully integrated high power density monolithic step-down regulators that satisfy challenging automotive and industrial requirements. They can be easily paralleled for efficient, high current applications and compact solution footprints.

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Ying Cheng

Ying Cheng

Ying Cheng is a staff applications engineer for power products in the Industrial and Multimarkets Business Group at Analog Devices in Santa Clara, California. She has been working at ADI since 2010. She currently provides applications support for non-isolated monolithic step-down converters. Ying Cheng’s interests in power management include high performance power converters and regulators of high efficiency, high power density, and low EMI for automotive, telecom, medical, and industrial applications. She received B.S.E.E. and M.S. degrees from Shanghai Jiao Tong University, China, and obtained a Ph.D. degree in electrical engineering from Missouri University of Science and Technology (formerly University of Missouri-Rolla), Rolla, Missouri. She can be reached at