advertisement Wide Input Range, High Efficiency DDR Termination Power Supply Achieves Fast Transient Response – Design Note 281 Wei Chen Introduction Today’s complicated computing and communication systems demand high system memory bandwidths. The emerging standard is Double Data Rate (DDR) memory because of its higher data rate and relatively low cost. A typical DDR memory system needs at least two main power supplies: VDD for the I/O power and V TT for the termination power. To ensure good signal quality and fast data rate, the termination power supply (V TT ) must always track the VDD with V TT = VDD/2. V TT can be as low as 0.6V. Since the termination resistors can carry current in either direction, the V TT power supply must be able to both source and sink current while tracking the VDD supply. A family of new termination/tracking controllers, including the LTC ®3717, LTC3718 and LTC3831, satisfy these DDR requirements. on-time programmed by the input voltage and output voltage. This scheme allows a fairly constant switching frequency while achieving an extremely fast load transient response. In addition, the controller’s minimum on-time is less than 100ns, allowing for a very small duty cycle at a very high switching frequency, thus minimizing the size of the inductor and capacitors. This circuit is suitable for high step-down applications such as 20V input and 1.25V output. The LTC3717 also includes a 5V internal LDO that can be used to drive an efficient logic-level power MOSFET. If an external 5V bias is available in the system, it can be applied to the EXTVCC pin to disable the internal 5V LDO and reduce the power loss of the controller at high input voltage. The reference tracking input of the LTC3717 is attenuated 50% internally, achieving a 0.65% regulation accuracy and eliminating the need for an external 1:1 resistor divider in the DDR termination power supply design. Overview of the LTC3717 The LTC3717 is a No RSENSE ™ current mode synchronous buck tracking controller that senses inductor current via the RDS(ON) of the bottom FET, eliminating the sense resistor and associated power loss. The LTC3717 implements a unique constant on-time architecture with L, LT, LTC, LTM, Linear Technology, the Linear logo and OPTI-LOOP are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. INTVCC CMDSH-3 1 2 PGOOD R5 10k C13 1000pF VIN VDD 2.5V R6 499k 1% VIN 4.5V TO 24V 0.33μF 0.1μF RUN/SS BOOST PGOOD TG LTC3717 3 INTVCC VRNG SW 4 ITH PGND C14 100pF 5 SGND BG 6 ION INTVCC 0.1μF 7 VFB VCC 8 VREF EXTVCC 16 Q1 Si7840DP 15 CIN 10μF 35V w4 D1 B340A L1 1.5μH 14 13 4.7μF Q2 Si7440DP 12 11 D3 B340A + + COUT 270μF 2V w2 47μF 25V 10μF 6.3V VTT 1.25V ±10A INTVCC 1Ω VIN 10 9 0.1μF 1μF 5V OPTIONAL COUT: PANASONIC EEFUEOD271R L1: CEP125-1R5MC DN282 F01 Figure 1. High Efficiency ±10A LTC3717 VTT Supply from 4.5V to 24V Input 04/02/281_conv Design Example Figure 1 shows a ±10A design using LTC3717. The input voltage can vary from 5V to 24V. The input voltage can be below 5V if an external 5V bias is available for powering the VCC pin of LTC3717. This design uses only two SO-8 PowerPak MOSFETs from Siliconix to deliver ±10A current. To achieve a higher output current, use an inductor with a higher current rating and lower RDS(ON) MOSFETs. This circuit achieves 84% efficiency at 250kHz switching frequency, 1.25V/10A output and 12V input, as shown in Figure 2. The combination of the unique constant on-time current mode architecture of LTC3717 and the OPTI-LOOP® compensation design produces an excellent load transient response. Figure 3 shows a typical load transient waveform. With only two SP output caps (270μF/2V), the output voltage variation is less than 100mV for a 10A load step. Conclusion The LTC3717 DDR termination power supply achieves high efficiency and fast load transient response for high input applications. If the available power sources are less than 5V, the LTC3718 can be used. The LTC3718 integrates an LTC3717 controller with a 1.2MHz boost regulator for the 5V MOSFET gate power. If the input voltage is between 3.3V and 8V, the LTC3831, a voltage mode synchronous buck tracking controller, can also be used. 100 EFFICIENCY (%) 90 80 LOAD CURRENT 5A/DIV 70 60 OUTPUT VOLTAGE VTT 100mV/DIV 50 40 2 0 4 8 6 LOAD CURRENT (A) 10 12 DN281 F03 TIME 20μs/DIV DN282 F02 Figure 2. Measured Efficiency at 1.25V Output, 12V Input Figure 3. Load Transient Waveforms 5V CMDSH-3 1 2 PGOOD R5 10k C13 1000pF INTVCC 3 4 C14 100pF 5 6 VIN R6 499k 1% VDD 2.5V 0.1μF VDD 2.5V 0.33μF 0.1μF 7 8 RUN/SS BOOST PGOOD TG LTC3717 VRNG SW ITH SGND PGND BG ION INTVCC VFB VCC VREF EXTVCC 16 Q1 Si7840DP 15 CIN 10μF 35V w4 D1 B340A L1 1.5μH 14 13 4.7μF Q2 Si7440DP 12 D3 B340A + 11 + COUT 270μF 2V w2 47μF 25V 10μF 6.3V VTT 1.25V ±10A 10 9 5V 0.1μF COUT: PANASONIC EEFUEOD271R L1: CEP125-1R5MC DN282 F04 Figure 4. High Efficiency ±10A LTC3717 VTT Supply from VDD Input Data Sheet Download www.linear.com Linear Technology Corporation For applications help, call (408) 432-1900 dn281f_conv LT/TP 0402 371.5K • PRINTED IN THE USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com © LINEAR TECHNOLOGY CORPORATION 2002