60V Input Monolithic Converter Powers Critical Circuits without Supercaps or Other Additional Components

Design Note DN1040: Introduction

The LTC3649 is a monolithic step-down regulator capable of operating from an input voltage range of 3.1V to 60V, and efficiently producing a (single) resistor-programmable output voltage at up to 4A of output current. These features alone make it a compelling industrial or automotive supply for output voltages from (VIN – 0.5V) to ground. One unique feature of the LTC3649 is that it is capable of providing power to critical systems when there is a power outage, without any extra components.

Hold-up circuits supply power to critical systems when the main power rail fails, allowing them to perform important housekeeping tasks, such as data retention, for a short period before all available energy is lost. Typical hold-up solutions employ dedicated controllers and large storage capacitors [1, 2] thus additional cost and complexity is warranted if the critical circuits require significant power and hold-up time. But if the required hold-up energy is relatively low, the LTC3649 can easily perform this task with no additional circuitry.

The dual output converter described herein works as a conventional step-down power supply under normal operating conditions. But during a power interruption, the converter itself becomes the energy source, maintaining the programmed output voltage to critical circuits. To perform this task, U1 becomes a step-up converter when input voltage is disconnected, discharging its output capacitor to provide hold-up energy.

Dual Output Converter and Hold-Up Circuit

Figure 1 shows a hold-up design using the LTC3649. Under normal conditions, the unregulated rail, VIN (VINS via a blocking diode) supplies a converter based on U1 (Converter A). This converter works in buck mode, generating a stable 5V on VOUT1. VINS is connected to a U2-based second converter (Converter B), which supplies 3.3V on VOUT2 to a critical load. When VIN fails, Converter A enters boost mode and maintains its programmed output voltage (VINS) by discharging its output filter capacitors CO1 and CO2. Resistors RIT and RIB program this voltage level. The PGOOD (PG) signal produced by U1 can be used to communicate the power failure to systems that can disconnect noncritical circuitry to preserve energy. The MODE/SYNC pin is left floating to allow the LTC3649 to enter boost mode.

Figure 1. The 5V Output Converter (U1) Provides Hold-Up Power for Protected Load on the 3.3V Output (U2). Note that the Pin MODE/SYNC of U1 Is Left Floating, Allowing the LTC3649 to Enter Boost Mode.

Figure 2 shows what happens to the LTC3649 in a boost mode. For the first 7ms of the capture, all voltages are stable. At 7ms, the power is turned off; both VIN and VINS begin to decline. When VINS reaches 8V, it stabilizes and the PG signal changes state, signaling the beginning of the VOUT1 collapsing. VINS remains at 8V as long as CO1 and CO2 have charge. VOUT2 holds constant during the entire process, supplying steady power to the critical load long after the power is interrupted.

Figure 2. When the Input Voltage VIN Drops, the Converter U1 Boosts VOUT1 to Maintain VINS at 8V. VINS Provides Power to Keep VOUT2 in Regulation for over 20ms after VIN Drops Out.


LTC3649 is a monolithic step-down regulator with integrated power MOSFETs. It is highly efficient, with low quiescent current, important in many battery operated systems. It is also highly versatile, with programmable frequency, a wide VIN range up to 60V and an output voltage range down to ground. It simplifies the design of automotive and industrial supplies, especially when its inherent ability as a hold-up circuit is taken into account.

Victor Khasiev

Victor Khasiev

Victor Khasievは、アナログ・デバイセズのシニア・アプリケーション・エンジニアです。パワー・エレクトロニクスの分野を担当しており、AC/DC変換とDC/DC変換の両方に関する豊富な経験を持ちます。また、車載用途や産業用途をターゲットとするアナログ・デバイセズのIC製品の使い方に関して、複数の記事を執筆しています。それらの記事では、昇圧、降圧、SEPIC、反転、負電圧、フライバック、フォワードに対応するコンバータや、双方向バックアップ電源などを取り上げています。効果的な力率改善の手法と高度なゲート・ドライバに関して2件の特許を保有しています。日々の業務では、顧客のサポートや、製品に関する質問への回答、電源回路の設計/検証、プリント回路基板のレイアウト、トラブルシューティング、システムの最終テストなどに取り組んでいます。