XRP6141ELMTR-F

XRP6141 35A Synchronous Step Down COT Controller December 2013 Rev. 1.0.1 GENERAL DESCRIPTION APPLICATIONS The XRP6141 is a synchronous step-down controller for point-of load supplies up to 35A. A wide 4.5V to 22V input voltage range allows for single supply operation from industry standard 5V, 12V and 19.6V rails. With a proprietary emulated current mode Constant On-Time (COT) control scheme, the XRP6141 provides extremely fast line and load transient response using ceramic output capacitors. It requires no loop compensation hence simplifying circuit implementation and reducing overall component count. The control loop also provides exceptional line regulation and maintains constant operating frequency. A selectable power saving mode, allows the user to operate in discontinuous mode (DCM) at light current loads thereby significantly increasing the converter efficiency. A host of protection features, including overcurrent, over-temperature, short-circuit and UVLO, help achieve safe operation under abnormal operating conditions. The XRP6141 is available in RoHS compliant, green/halogen free space-saving 16-pin 3x3 QFN package. • Networking and Communications • Fast Transient Point-of-Loads • Industrial and Medical Equipment • Embedded High Power FPGA FEATURES • 35A Capable Step Down Controller − Wide Input Voltage Range o o 5V to 22V Single Supply 4.5V to 5.5V Low Vin − Integrated high Current 2A/3A Drivers − 0.6V to 18V Adjustable Output Voltage • Proprietary Constant On-Time Control − No Loop Compensation Required − Ceramic Output Cap. Stable operation − Programmable 200ns-2µs − Constant 200kHz-800kHz Frequency − Selectable CCM or CCM/DCM Operation • Programmable hiccup current limit with thermal compensation • Precision Enable and Power-Good Flag • Programmable Soft-start • Integrated Bootstrap diode • 16-pin QFN Package TYPICAL APPLICATION DIAGRAM Fig. 1: XRP6141 Application Diagram Exar Corporation 48720 Kato Road, Fremont CA 94538, USA www.exar.com Tel. +1 510 668-7000 – Fax. +1 510 668-7001 XRP6141 35A Synchronous Step Down COT Controller ABSOLUTE MAXIMUM RATINGS OPERATING RATINGS These are stress ratings only and functional operation of the device at these ratings or any other above those indicated in the operation sections of the specifications below is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability. VIN ........................................................... -0.3V to 22V VCC .......................................................... -0.3V to 5.5V SW, ILIM ................................................... -1V to 26V1 PGOOD, VCC, TON, SS, EN, GL, FB ............ -0.3V to 5.5V Switching Frequency ............................. 200kHz-800kHz3 Junction Temperature Range ....................-40°C to 125°C VIN ............................................................ -0.3V to 28V VCC .......................................................... -0.3V to 6.0V BST ......................................................... -0.3V to 34V2 BST-SW ...................................................... -0.3V to 6V SW, ILIM .................................................. -5V to 28V1,2 GH................................................... -0.3V to BST+0.3V GH-SW........................................................ -0.3V to 6V ALL other pins ................................... -0.3V to VCC+0.3V Storage Temperature .............................. -65°C to 150°C Junction Temperature .......................................... 150°C Power Dissipation ................................ Internally Limited Lead Temperature (Soldering, 10 sec) ................... 300°C ESD Rating (HBM - Human Body Model) .................... 2kV Note 1: SW pin’s minimum DC range is -1V, transient is -5V for less than 50ns Note 2: No external voltage applied Note 3: Recommended ELECTRICAL SPECIFICATIONS Specifications are for Operating Junction Temperature of TJ = 25°C only; limits applying over the full Operating Junction Temperature range are denoted by a “•”. Minimum and Maximum limits are guaranteed through test, design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise indicated, VIN = 12V, BST=VCC, SW=GND=PGND=0V, CGH=CGL=3.3nF. Parameter Min. Typ. Max. Units Conditions Power Supply Characteristics 5 12 22 4.5 5.0 5.5 IVIN, VIN supply current 0.7 2 mA IVCC, VCC Quiescent current 0.7 2 mA VIN, Input Voltage Range V • VCC regulating VCC tied to VIN • Not switching, VIN=12V, VFB=0.7V • Not switching, VCC=VIN=5V, VFB=0.7V IVIN, VIN supply current 11 mA f=300kHz, RON=108.8k, VFB=0.58V IOFF, Shutdown current 0.1 μA Enable=0V, VIN=12V Enable and Under-Voltage Lock-Out UVLO VIH_EN, EN Pin Rising Threshold 1.8 VEN_HYS, EN Pin Hysteresis VIH_EN, EN Pin Rising Threshold for DCM/CCM operation 2.0 50 2.9 VEN_HYS, EN Pin Hysteresis VCC UVLO start threshold, rising edge 1.9 3.0 3.1 100 4.00 VCC UVLO Hysteresis 4.25 V • mV V • mV 4.50 200 V • mV Reference voltage 0.597 0.600 0.603 V VIN =5V-22Và VCC regulating 0.596 0.604 V VIN =4.5V-5.5Và tie VCC to VIN 0.594 0.600 0.606 V DC Line regulation ±0.1 % CCM operation, closed loop, applies to any COUT DC Load regulation ±0.25 % CCM operation, closed loop, applies to any VREF, Reference voltage © 2013 Exar Corporation 2/14 • VIN =5V-22Và VCC regulating, VIN =4.5V-5.5Và tie VCC to VIN Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller Parameter Min. Typ. Max. Units Conditions COUT Programmable Constant On-Time On-Time 1 f corresponding to On-Time 1 1855 2182 2509 ns 217 250 294 kHz Minimum Programmable On-Time On-Time 2 109 VIN=22V, VOUT=12V ns RON = 7.059kΩ, VIN=22V • RON = 7.059kΩ, VIN=12V 170 200 230 ns f corresponding to On-Time 2 1618 1375 1196 kHz f corresponding to On-Time 2 490 417 362 kHz On-Time 3 391 460 529 ns 250 350 ns Minimum Off-Time • RON = 141.2kΩ, VIN=22V VOUT=3.3V VOUT=1.0V • RON = 16.235kΩ, VIN=12V • Diode Emulation Mode Zero crossing threshold -4 -1 -14 -10 DC value measured during test mV SoftStart SS Charge current -6 µA SS Discharge current mA 1 VCC Linear Regulator (VCC should be tied to VIN, for 4.5V ≤VIN≤5.5V) VCC Output Voltage Dropout Voltage 4.8 5.0 4.51 4.7 5.2 200 300 490 -10 -7.5 -5 % 2 4 % V mV • • Fault present • VIN=6V to 22V, Iload=0 to 30mA • VIN=5V, Iload=0 to 20mA • IVCC=30mA Power Good Output Power Good Threshold Power Good Hysteresis Power Good Sink Current mA 1 Protection: OCP, OTP, Short-circuit Hiccup timeout ILIM pin source current 110 45 ILIM current temperature coeff. OCP comparator offset 50 ms 55 0.4 -8 0 µA %/°C +8 mV • Current limit blanking 100 ns GL rising>1V Thermal shutdown threshold1 150 °C Rising temperature 15 °C Thermal Hysteresis1 VSCTH Feedback pin short-circuit threshold 50 60 70 % 1.35 2.0 Ω • Percent of VREF, short circuit is active After PGOOD is up Output Gate drivers GH Pull-Down Resistance GH Pull-up Resistance IGH=200mA 1.8 2.8 Ω IGH=200mA 1.35 1.9 Ω IGL=200mA GL Pull-up Resistance 1.7 2.7 Ω IGL=200mA GH and GL pull-down Resistance 50 --- kΩ GH and GL rise time 35 50 ns 10% to 90% GH and GL fall time 30 40 ns 90% to 10% GL Pull-Down Resistance GL to GH non-overlap time 20 30 60 ns Measured GL falling edge =1V to GH rising edge =1V, BST=VCC, SW=0V GH to GL non-overlap time 15 20 40 ns Measured GH falling edge =1V to GL rising edge =1V Note 1: Guaranteed by design © 2013 Exar Corporation 3/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller BLOCK DIAGRAM VCC TON VCC UVLO Enable LDO VIN 4.25 V LDO Switching Enabled + - VCC VCC OTP TJ 150 C + ESR emulation & DC correction - PGOOD On-Time + - Switching Enabled BST 0.6 V Feedback comparator TON + - R Q S Q PGOOD comparator + 0.555 V + - Enable LDO EN/Mode 1.9 V + R Q S Q -1 mV Hiccup Mode Enable LDO - If four consecutive OCP If 8 consecutive ZCD Then DCM If 1 non-ZCD Then exit DCM + - Zero Cross Detect SW GL Enable Hiccup Forced CCM or DCM/CCM 3V SW VCC Switching Enabled Short-circuit detection 0.36 V GH Dead Time Control Minimum On Time - 50uA + - FB VIN 10uA SS OCP comparator + - AGND ILIM PGND Fig. 2: XRP6141 Block Diagram PIN ASSIGNMENT GL 1 NC 2 PGND VCC VIN AGND 16 15 14 13 12 AGND 11 FB EXPOSED PAD SW 3 GH 4 10 PGOOD 9 5 6 7 8 BST ILIM EN TON SS Fig. 3: XRP6141 Pin Assignment © 2013 Exar Corporation 4/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller PIN DESCRIPTION Name Pin Number Description GL 1 Driver output for Low-side N-channel synchronous MOSFET. NC 2 Internally not connected. Leave this pin floating. SW 3 Lower supply rail for high-side gate driver GH. Connect this pin to the junction between the two external N-channel MOSFETs. GH 4 Driver output for high-side N-channel switching MOSFET. BST 5 High-side driver supply pin. Connect a 0.1uF bootstrap capacitor between BST and SW. ILIM 6 Over-current protection programming. Connect with a resistor to the Drain of the lowside MOSFET. EN/MODE 7 Precision enable pin. Pulling this pin above 1.9V will turn the IC on and it will operate in Forced CCM. If the voltage is raised above 3.0V then the IC will operate in DCM or CCM depending on load. TON 8 Constant on-time programming pin. Connect with a resistor to AGND. SS 9 Soft-Start pin. Connect an external capacitor between SS and AGND to program the soft-start rate based on the 10uA internal source current. PGOOD 10 Power-good output. This open-drain output is pulled low when VOUT is outside the regulation. FB 11 Feedback input to feedback comparator. Connect with a set of resistors to VOUT and GND in order to program VOUT. AGND 12, 13 VIN 14 VCC 15 The output of LDO. For operation using a 5V rail, VCC should be shorted to VIN. PGND 16 Low side driver ground Analog ground. Control circuitry of the IC is referenced to this pin. IC supply input. Provides power to internal LDO. Thermal pad for heat dissipation. Connect to AGND with a short trace. Exposed Pad ORDERING INFORMATION Part Number Temperature Range XRP6141EL-F -40°C≤TJ≤+125°C XRP6141ELMTR-F -40°C≤TJ≤+125°C XRP6141ELTR-F XRP6141EVB Marking Package Packing Quantity 6141 YWW XXXX 3x3mm QFN16 250/Tape & Reel -40°C≤TJ≤+125°C XRP6141 Evaluation Board Tray 3k/Tape & Reel Note 1 Lead Free and/or Halogen Free “Y” = Year – “WW” = Work Week – “X” = Lot Number; when applicable. © 2013 Exar Corporation 5/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller TYPICAL PERFORMANCE CHARACTERISTICS All data taken at VIN = 12V, VOUT=1.2V, f=300kHz, TA = 25°C, unless otherwise specified - Schematic and BOM from Application Information section of this datasheet. 1.250 1.250 +1% 1.240 1.220 1.220 1.210 1.210 1.200 1.190 1.190 1.180 1.170 1.170 1.160 1.160 1.150 0 5 10 15 20 -1% 1.200 1.180 1.150 Typical 1.230 -1% VOUT (V) VOUT (V) 1.230 +1% 1.240 Typical 25 5 10 15 20 VIN (V) IOUT (A) Fig. 5: Line regulation, IOUT=25A Fig. 4: Load regulation, VIN=12V SW SW VOUT VOUT IL IL 20ms/d 2us/d Fig. 6: VOUT ripple is 22mV at 25A, 12VIN, 1.2VOUT Fig. 7: VOUT ripple is 22mV at 0A, DCM, 12VIN, 1.2VOUT VIN VIN VOUT VOUT SW SW IL IL Fig. 8: Powerup, Forced CCM, IOUT=0A Fig. 9: Powerup, Forced CCM, IOUT=25A © 2013 Exar Corporation 6/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller VIN VIN VOUT VOUT SW SW IL IL Fig. 11: Powerup, DCM/CCM, IOUT=25A 100% 100% 95% 95% 90% 90% Efficiency Efficiency Fig. 10: Powerup, DCM/CCM, IOUT=0A 85% 80% 75% Forced CCM 70% 80% 75% Forced CCM 70% DCM/CCM DCM/CCM 65% 65% 60% 85% 60% 0.1 1 10 0.1 IOUT (A) 100% 100% 95% 95% 90% 90% 85% 80% 75% Forced CCM 85% 80% 75% Forced CCM 70% DCM/CCM DCM/CCM 65% 65% 60% 10 Fig. 13: Efficiency, 5VIN, 1.2VOUT, 0.47uH, 300kHz Efficiency Efficiency Fig. 12: Efficiency, 5VIN, 1.8VOUT, 0.47uH, 300kHz 70% 1 IOUT (A) 60% 0.1 1 10 IOUT (A) 1 10 IOUT (A) Fig. 14: Efficiency, 5VIN, 1.0VOUT, 0.47uH, 300kHz © 2013 Exar Corporation 0.1 Fig. 15: Efficiency, 12VIN, 3.3VOUT, 1uH, 300kHz 7/14 Rev. 1.0.1 XRP6141 100% 100% 95% 95% 90% 90% 85% 85% Efficiency Efficiency 35A Synchronous Step Down COT Controller 80% 75% Forced CCM 70% 75% Forced CCM 70% DCM/CCM DCM/CCM 65% 65% 60% 80% 60% 0.1 1 10 0.1 IOUT (A) 100% 100% 95% 95% 90% 90% 85% 80% 75% Forced CCM 85% 80% 75% Forced CCM 70% DCM/CCM DCM/CCM 65% 65% 60% 10 Fig. 17: Efficiency, 12VIN, 1.8VOUT, 1uH, 300kHz Efficiency Efficiency Fig. 16: Efficiency, 12VIN, 2.5VOUT, 1uH, 300kHz 70% 1 IOUT (A) 60% 0.1 1 10 0.1 1 10 IOUT (A) IOUT (A) Fig. 18: Efficiency, 12VIN, 1.2VOUT, 0.47uH, 300kHz Fig. 19: Efficiency, 12VIN, 1.0VOUT, 0.47uH, 300kHz EN VIN VOUT IL 1ms/d Fig. 20: Enable turn on/turn off, 12VIN, 1.2VOUT, 25A © 2013 Exar Corporation 8/14 Rev. 1.0.1 XRP6141 400 610 350 605 VREF (mV) f (kHz) 35A Synchronous Step Down COT Controller 300 250 200 600 595 590 0 5 10 15 20 25 -40 -20 0 20 IOUT (A) 40 60 80 100 120 Tj (°C) Fig. 22: frequency versu IOUT, Forced CCM Fig. 23: VREF versus temperature 500 70 490 480 60 460 ILIM (uA) TON (ns) 470 450 440 430 50 40 420 410 400 -40 -20 0 20 40 60 80 30 100 120 Tj (°C) -20 0 20 40 60 80 100 120 Tj (°C) Fig. 24: On-Time versus temperature Fig. 25: ILIM versus temperature IL IL VOUT SW -40 VOUT SW 20us/d Fig. 26: Load step, DCM/CCM, 0A-25A-0A © 2013 Exar Corporation 20us/d Fig. 27: Load step, Forced CCM, 0A-25A-0A 9/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller IL DETAILED OPERATION TON XRP6141 is a synchronous step-down proprietary emulated current-mode Constant On-Time (COT) controller. The on-time, which is programmed via RON, is inversely proportional to VIN and maintains a nearly constant frequency. The emulated current-mode control allows the use of ceramic output capacitors. TOFF IOUT IL > 1mV / Rds Each switching cycle begins with GH signal turning the high-side (switching) FET for a preprogrammed time. At the end of the on-time the high-side FET is turned off and the low-side (synchronous) FET is turned on for a preset minimum time (250ns nominal). This parameter is termed Minimum Off-Time. After the minimum off-time the voltage at the feedback pin FB is compared to an internal voltage ramp at the feedback comparator. When VFB drops below the ramp voltage, the high-side FET is turned on and the cycle repeats. This voltage ramp constitutes an emulated current ramp and makes possible the use of ceramic capacitors, in addition to other capacitor types, for output filtering. 1mV/Rds 0A VSW VIN 0V -1mV ENABLE/MODE EN/MODE pin accepts a tri-level signal that is used to control turn on/off. It also selects between two modes of operation: ‘Forced CCM’ and ‘DCM/CCM’. If EN is pulled below 1.9V the IC shuts down. A voltage between 1.9V and 3V selects the Forced CCM mode, which will run the converter in continuous conduction at all times. A voltage higher than 3V selects the DCM/CCM mode, which will run the converter in discontinuous conduction at light loads. DCM/CCM, which is based on diode emulation, is described below. IL x Rds < -1mV Figure 28. Continuous conduction during diode emulation IL TON TOFF Diode Emulation Mode (DCM/CCM) IOUT Diode Emulation Mode is designed to increase the converter efficiency at light loads. Light-load efficiency is increased by preventing negative inductor current. This is achieved by monitoring the inductor current valley (bottom) via SW and turning off the synchronous FET as inductor current IL approaches zero. IL is monitored indirectly by monitoring VSW during the synchronous FET conduction (i.e., VSW=IL x Rds). If VSW does not drop to 1mV the converter operates in continuous conduction as shown in figure 28. If VSW equals -1mV then a zerocrossing is detected (figure 29). Eight consecutive zerocrossings activate the diode emulation mode. Then, on every subsequent switching cycle, GL is turned off when VSW reaches -1mV (figure 30). If IOUT decreases further, discontinuous conduction ensues (figure 30). The constant on-time delivers a fixed energy at the start of each switching cycle. The synchronous FET is turned off when VSW drops to -1mV. Remaining inductor energy is discharged through the FET’s body diode. Now, because IOUT is low, it takes longer for VOUT to drop below regulation and trigger a new switching cycle. Hence switching frequency f decreases. This increase the efficiency at light loads. © 2013 Exar Corporation 1mV/Rds 0A IL = 1mV / Rds VSW VIN 0V -1mV IL x Rds = -1mV àZero-Cross detected Figure 29. Zero-Crossing detection 10/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller IL Where: TON TOFF RLIM is resistor value for programming IOCP IOCP is the overcurrent value to be programmed RDS is the MOSFET rated on resistance 8mV is the OCP comparator offset IOUT ILIM is the internal current that generates the necessary OCP comparator threshold (use 45uA) 1mV/Rds 0A VSW Note that ILIM has a positive temperature coefficient of 0.4%/°C. This is meant to roughly match and compensate for positive temperature coefficient of the synchronous FET. In order for this feature to be effective the temperature rise of the IC should approximately match the temperature rise of the FET. IL = 1mV / Rds VIN VOUT SHORT-CIRCUIT PROTECTION (SCP) 0V If the output voltage drops below 60% of its programmed value, the IC will enter hiccup mode. Hiccup will persist until short-circuit is removed. SCP circuit becomes active after PGOOD asserts high. -1mV IL x Rds = -1mV à GL is turned off Figure 30. emulation Discontinuous conduction during OVER-TEMPERATURE PROTECTION (OTP) diode OTP triggers at a nominal die temperature of 150°C. The gate of switching FET and synchronous FET are turned off. When die temperature cools down to 135°C, softstart is initiated and operation resumes. PROGRAMMING THE ON-TIME PROGRAMMING THE OUTPUT VOLTAGE The on-time TON is programmed via resistor RON according to following equation: Use an external voltage divider as shown in figure 1 to program the output voltage VOUT. (3.4𝐸 − 10) × 𝑅𝑂𝑁 𝑇𝑂𝑁 = 𝑉𝐼𝑁 𝑉𝑂𝑈𝑇 − 1� 𝑅1 = 𝑅2 × � 0.6 R2 recommended range is 2k Ω to 10kΩ. The required TON for a given application is calculated from: 𝑇𝑂𝑁 = PROGRAMMING THE SOFTSTART 𝑉𝑂𝑈𝑇 𝑉𝐼𝑁 × 𝑓 Place a capacitor CSS between the SS and GND pins to program the softstart. In order to program a softstart time of TSS, calculate the required capacitance CSS from the following equation: Note that switching frequency f will increase somewhat, as a function of increasing load current and increasing losses (see figure 22). 𝐶𝑆𝑆 = 𝑇𝑆𝑆 × 10𝑢𝐴 0.6𝑉 OVER-CURRENT PROTECTION (OCP) FEED-FORWARD CAPACITOR CFF If load current exceeds the programmed overcurrent IOCP for four consecutive switching cycles, then IC enters hiccup mode of operation. In hiccup the MOSFET gates are turned off for 110ms (hiccup timeout). Following the hiccup timeout a soft-start is attempted. If OCP persists, hiccup timeout will repeat. The IC will remain in hiccup mode until load current is reduced below the programmed IOCP. In order to program overcurrent protection use the following equation: A feed-forward capacitor CFF is recommended. CFF provides a low-impedance/high-frequency path for the output voltage ripple to be transmitted to FB. It also helps get an optimum load transient response. Calculate CFF from: 𝑅𝐿𝐼𝑀 = (𝐼𝑂𝐶𝑃 × 𝑅𝐷𝑆) + 8𝑚𝑉 𝐼𝐿𝐼𝑀 © 2013 Exar Corporation 𝐶𝐹𝐹 = 11/14 1 2 × 𝜋 × 𝑓𝑠 × 0.1 × 𝑅1 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller Applications Circuit D1 MMSZ4699T1G R9 2.5k, R8 1k, R7 6k, R6 2k J1 1 2 3 1 2 3 Forced CCM DCM/CCM EN/MODE RLIM 1.8k,1% 11.8k EXPAD 5 BST ILIM GL 13 AGND NC 4 L1 IHLP-5050FD-01 CVCC 2 1 MB FDMS7650DC T8 C5 22uF T9 T10 VIN- Csnub 6.8nF C5,C6,C7,C8 POSCAP 2R5TPE330M7 1.2V @ 0-25A VOUT+ C6 C7 C8 C9 C10 C11 C12 C13 T1 330uF 330uF 330uF 330uF OPEN OPEN OPEN OPEN T2 Rsnub 1 Ohm VOUT- R3 0 Ohm CFF 0.56nF 0.1uF 4.7uF C4 22uF 0.47uH @ 41A, 1mOhm 3 T7 CIN C3 22uF T6 PGND AGND VCC 17 U1 XRP6141 FB SW T5 16 12 15 11 VIN 10k PGOOD C2 22uF FDMS7578 RBST 0 Ohm GH AGND R4 SS 14 9 10 EN TON 47nF PWRGD 6 8 CSS C1 22uF VIN+ MT CBST 1uF 7 RON 12V C1,C2,C3,C4 CERAMIC 1210 X7R VIN R1 10k,1% T3 R5 OPEN R2 10k,1% VIN T4 VCC Note: If jumper J1 is set to CCM position, the converter will operate in ‘Forced CCM’ at VIN=12V(+/-10%). In order to operate in Forced CCM over a wider VIN range, remove Jumper and apply an auxilary voltage in the 1.9V-3V range to the EN/MODE test point. If jumper J1 is set to DCM/CCM position the converter will operate at DCM or CCM, depending on load, at VIN=12V(+/10%). In order to operate in DCM/CCM over a wider VIN range, remove Jumper and apply an auxilary voltage in the 3.1V5V range to the EN/MODE test point. © 2013 Exar Corporation 12/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller PACKAGE SPECIFICATION © 2013 Exar Corporation 16 PIN 3X3 QFN 13/14 Rev. 1.0.1 XRP6141 35A Synchronous Step Down COT Controller REVISION HISTORY Revision Date Description 1.0.0 12/16/2013 Initial release 1.0.1 12/20/2013 Specification improvement FOR FURTHER ASSISTANCE Email: customersupport@exar.com powertechsupport@exar.com Exar Technical Documentation: http://www.exar.com/TechDoc/default.aspx? EXAR CORPORATION HEADQUARTERS AND SALES OFFICES 48720 Kato Road Fremont, CA 94538 – USA Tel.: +1 (510) 668-7000 Fax: +1 (510) 668-7030 www.exar.com NOTICE EXAR Corporation reserves the right to make changes to the products contained in this publication in order to improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. Charts and schedules contained here in are only for illustration purposes and may vary depending upon a user’s specific application. While the information in this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies. EXAR Corporation does not recommend the use of any of its products in life support applications where the failure malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation receives, writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the user assumes such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances. or its in all Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited. © 2013 Exar Corporation 14/14 Rev. 1.0.1