SiP12202 Vishay Siliconix Synchronous Step Down Controller DESCRIPTION SiP12202 is a synchronous step down controller designed for use in dc-dc converter circuits requiring output currents as high as 10 amperes. SiP12202 is designed to require a minimum number of external components, simplifying design and layout. It accepts input voltages from 2.7 V to 5.5 V, providing an adjustable output with voltage ranging from 0.6 V to 5.5 V. SiP12202 includes a combination Compensation/ Shutdown pin. Protection features include undervoltage lockout, Power Good output, output current limit, and thermal shutdown. SiP12202 is available in a lead (Pb)-free MLP-33-10 package and is specified to operate over the range of - 40 C to 85 C. FEATURES * 2.7 V to 5.5 V Input Voltage Range * Adjustable Output Voltage - 0.6 to 5.5 V * For Converter loads up to 10 A * High efficiency - 93 % * Uses High Side P-Channel MOSFET * Uses Low Side N-Channel MOSFET * 500 kHz operation * Internal Soft Start * Power Good Indication * Shutdown Pin * Output Current Limit * Minimum External Components * MLP33-10 Package APPLICATIONS * * * * * Distributed Power Desktop & Notebook Computers Battery Operated Equipment Point of Load Regulation DSP Cores TYPICAL APPLICATION CIRCUIT VIN VIN VIN DH LX Power Good Compensation/ Shutdown VOUT PG DL COMP/SD FB PGND AGND AGNDP GND GND Document Number: 73542 S-52332-Rev. B, 07-Nov-05 www.vishay.com 1 SiP12202 Vishay Siliconix ABSOLUTE MAXIMUM RATINGS Parameter VIN, LX to GND FB, PG, Comp/SD to GND Limit 6 - 0.3 to 6 560 125 - 55 to + 150 Power Dissipationa, b Maximum Junction Temperature Storage Temperature Notes a. Device mounted with all leads soldered or welded to PC board b. Derate 14 mW/C above + 85 C Unit V mW C Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating/conditions for extended periods may affect device reliability. RECOMMENDED OPERATING RANGE Parameter Input Voltage Range Output Voltage Adjustment Range Operating Temperature Range Limit 2.7 to 5.5 0.6 to 5.5 - 40 to + 85 Unit V C SPECIFICATIONS Parameter Symbol Test Condition Unless Specified VIN = 5.0 Limits - 40 to 85 C Mina Typb Unit Maxa Controller Input Voltage VIN Quiescent Current Switching Oscillator Frequency Oscillator Ramp Amplitude Feedback Voltage 2.7 Non Switching fOSC 400 VOSC VFB FB input Bias Current IFB Transconductance GM 5.5 V 0.6 1 mA 500 600 kHz V 1 TA = 25 C 0.591 0.600 0.585 0.609 0.615 100 Soft Start V nA 2 mA/V 4 ms Inputs and Outputs SD Input Voltage VIL Shutdown Current IIL 30 tBBM 30 0.15 V 60 A MOSFET Drivers Break-before-make-time ns Highside Driver Output Voltage On resistance VDH V 4.5 RDSHH VIN = 4.5 V 1.3 1.9 RDSHL VIN = 4.5 V 2.8 4.4 Rise time - PFET Turn On trH VIN = 5 V, CL = 2.7 nF 64 Fall time - PFET Turn Off tfH VIN = 5 V, CL = 2.7 nF 8 ns Lowside Driver Output Voltage VDL V 4.5 RDSLH VIN = 4.5 V 5.5 8.2 RDSLL VIN = 4.5 V 0.85 1.4 Rise time - NFET Turn On trL VIN = 5 V, CL = 2.7 nF 83 Fall time - NFET Turn Off tfL VIN = 5 V, CL = 2.7 nF 6.6 On resistance www.vishay.com 2 ns Document Number: 73542 S-52332-Rev. B, 07-Nov-05 SiP12202 Vishay Siliconix SPECIFICATIONS Parameter Symbol Test Condition Unless Specified VIN = 5.0 Limits - 40 to 85 C Mina Unit Typb Maxa 2.4 2.5 Protection Rising VUVLO Under voltage lockout 2.3 UVLO-Hysteresis 0.10 V Power Good PG Output Voltage VPGOL ISINK = 0.5 mA 0.4 V PG Leakage Current IPGOL VPG = 5 V 1 A PG Voltage Threshold VETH PG Threshold Hysteresis VEH 70 %VOUT 5 %VOUT 165 C 20 C Over Current Limit Thermal Shutdown Temperature Rising Thermal Hysteresis MOSFET On Voltage Sense Threshold With respect to VIN VDL - 335 - 300 - 265 mV NOTES: a) The algebriac convention whereby the most negative value is a minimum and the most positive a maximum. b) Typical values are for DESIGN AID ONLY, not guaranteed nor subject to production testing. PIN CONFIGURATION PIN DESCRIPTION Part Number Name 1 COMP/SD Function Combination Compensation and Shut down pin 2 FB 3 AGND Feedback input 4 PG Indicates that the output voltage is in regulation 5, 10 VIN Input voltage 6 DL Lowside gate drive 7 PGND 8 LX Connection for the inductor node 9 DH Highside gate drive Analog Ground Power Ground ORDERING INFORMATION Part Number Temperature Range Package SiP12202DM-T1-E3 - 40 to 85 C MLP33-10 Eva Kit Temperature Range Board SiP12202DB - 40 to 85 C Surface Mount Document Number: 73542 S-52332-Rev. B, 07-Nov-05 www.vishay.com 3 SiP12202 Vishay Siliconix FUNCTIONAL BLOCK DIAGRAM SiP12202 0.45 V PG FB Vin Vin Over Temp UVLO Soft Start DH Over Voltage Shut Down Comp LX Over Current Sense FB Gate Control Logic GM PWM Comp BBM 0.6 V Vin OSC 500KHz Vosc DL Pgnd SD/Comp Agnd DETAILED OPERATIONAL DESCRIPTION Enable/ON State: The COMP/SD pin has 10 A pull up current to ensure auto startup as soon as the pin is released by the external pull down MOS. When the internal reference is ready, there will be a clamp current applied at COMPSD; this is to ensure the COMPSD pin will not go below 600 mV inadvertently due to the amplifier excursion or noise. The COMPSD has to go above 600 mV to enable the chip fully. Disable/Shutdown/Off State To disable the chip, the COMP/SD pin has to pulled below 150 mV typically and the external pull down MOSFET has to be able to sink at least 250 A. Once the pin reaches a voltage below the 150 mV level, the chip will go into shutdown mode with only essential curcuitry alive and the current bias of the chip will be cut down to 30 A level typically. Both High Side and Low Side Gates are off. UVLO: The chip enters into Under Voltage Lockout when VIN is below 2.3 V (typical). Both High Side Gate and Low Side Gate will be turned off. The chip will go out of UVLO mode when VIN is above 2.4 V (typical). Soft Start: Once the chip is out of shutdown and UVLO mode the soft start is initiated. The soft start is done accomwww.vishay.com 4 plished by ramping up the internal reference. During soft start mode the chip can not enter into fault mode. If there is an over current condition (current limit condition), the High Side Gate will be turned off and the Low Side will be turned on. Once the soft start timing elapses, the chip enters into a normal state of operation. Output Over Voltage State: When the Output voltage goes above 1.083 times nominal Output Voltage, the over voltage circuit will act as a high speed clamp and the High Side Gate will be turned off and the Low Side Gate will be on. The condition will persist until the Output voltage drops below the trigger voltage minus a hysteresis. Output Over Current State: The SiP12202 will enter a cycle by cycle over current condition when the voltage on the LX pin falls below VIN by 300 mV. During the over current condition the High Side MOSFET is turned off for the duration of the existing cycle. At the beginning of the next cycle the High Side MOSFET turns on and the LX voltage is measured again. If the over current condition still exists, the High Side MOSFET is turned off again. This is repeated seven consecutive times after which the IC will go into a fault state. If the over current condition is removed before seven consecutive cycles the IC reverts to normal operating mode. Document Number: 73542 S-52332-Rev. B, 07-Nov-05 SiP12202 Vishay Siliconix TYPICAL CHARACTERISTICS 100 Vout = 3.3 V 95 90 EFFICIENCY (%) Fault State: The IC can only enter into Fault mode after the soft start mode has ended and seven consecutive over current condition cycles has occurred. Once it enters the Fault state, with the High Side MOSFET turned off and the Low Side MOSFET turned on, any occurring over current condition will be ignored. The Fault State will last for seven soft start cycles. After which the IC will enter Soft Start mode. If the over current condition is removed the IC will operate normally, otherwise the over current sequence is repeated. This fault scheme minimizes thermal stress on the external power MOSFET switches Vout = 2.5 V 85 80 75 70 65 60 55 Vin = 5.0 V 50 0 Over Temperature: When the temperature of the chip goes above 165 C, the chip enters into over temperature shutdown. The High Side gate will be off and the Low Side gate will be on. Only system monitor circuitry will be active. Once the temperature of the chip drops below 145 C, the chip enters into the normal operation mode. ( VV OUT FB -1 6 8 10 EFFICIENCY vs LOAD CURRENT 600 550 Vin = 5.0 V 500 Vin = 2.7 V 450 Setting the Output Voltage: An output voltage between 0.6 V and VIN and can be configured by connecting FB pin to a resistive divider between the output and GND. Select resistor R2 in the 1 k to 10 k range. R1 is then given by: R1 = R2 4 LOAD CURRENT (A) FREQUENCY (kHz) Power Good: Power Good State: When the output is above 0.75 times nominal output voltage, the PC signal will be high to indicate that the output voltage is available for external use. The PG pin requires a pull up resistor. 2 400 -45 -10 25 60 95 130 TEMPERATURE (C) OSCILLATOR FREQUENCY Vs TEMPERATURE 0.615 ) VOLTAGE ( V) where VFB = 0.6 V VOUT R1 0.605 Vin = 2.7 V to 5.0 V 0.595 FB R2 0.585 -45 -10 25 60 95 130 TEMPERATURE (C) FEEDBACK THRESHOLD Vs TEMPERATURE 0.6 V Document Number: 73542 S-52332-Rev. B, 07-Nov-05 www.vishay.com 5 SiP12202 Vishay Siliconix - 260 2.5 - 280 2.45 VOLTAGE ( V) VOLTAGE (mV) TYPICAL CHARACTERISTICS Vin = 2.7 V - 300 Vin = 5.0 V 2.4 2.35 - 320 2.3 - 340 - 45 - 10 25 60 95 130 - 45 - 10 25 60 95 TEMPERATURE (C) TEMPERATURE (C) CURRENT SENSE VOLTAGE Vs TEMPERATURE UVLO Vs TEMPERATURE 130 10 0.8 CURRENT (nA) CURRENT (mA) 5 Vin = 5.0 V 0.6 Vin = 2.7 V 0.4 - 45 - 10 25 60 95 Vin = 2.7 V 0 Vin = 5.0 V -5 - 10 - 45 130 25 60 95 130 TEMPERATURE (C) FB INPUT BIAS CURRENT Vs TEMPERATURE TEMPERATURE (C) QUIESCENT CURRENT Vs TEMPERATURE 80 50 VOLTAGE (% VOUT) 40 CURRENT (mA) - 10 Vin = 5.0 V 30 Vin = 5.0 V 75 Vin = 2.7 V 20 Vin = 2.7 V 10 70 - 45 - 10 25 60 95 TEMPERATURE (C) SHUTDOWN CURRENT Vs TEMPERATURE www.vishay.com 6 130 - 45 - 10 25 60 95 130 TEMPERATURE (C) POWER GOOD THRESHOLD Vs TEMPERATURE Document Number: 73542 S-52332-Rev. B, 07-Nov-05 SiP12202 Vishay Siliconix TYPICAL WAVEFORMS VLX = 5 V/div VOUT = 500 mV/div DH = 5 V/div DL = 5 V/div Inductor Current 5 A/div 1 s/div VIN = 5 V, VOUT = 2.5 V, Load Current = 5 A, L = 1.5 H, COUT = 220 F x 2 Typical Switching Waveform Inductor Current 5 A/div 10 s/div VIN = 5 V, VOUT = 2.5 V, Load Current = 1 A to 8 A Step, L = 1.5 H, COUT = 220 F x 2 Load Transient Response Comp/SD = 1 V/div VOUT = 1 V/div PG = 5 V/div VOUT = 20 mV/div Inductor Current 5 A/div 1 ms/div VIN = 5 V, VOUT = 2.5 V, Load Current = 1 A, Output Filter Cap = 220 F x 2 Soft Start 1 s/div VIN = 5 V, VOUT = 2.5 V, Load Current = 1 A, L = 1.5 H, COUT = 220 F x 2 Output Voltage Ripple Comp/SD = 1 V/div VOUT = 1 V/div Inductor Current 5 A/div 1 ms/div VIN = 5 V, VOUT = 2.5 V, Load Current = 1 A, Output Filter Cap = 220 F x 2 Shut Down Document Number: 73542 S-52332-Rev. B, 07-Nov-05 www.vishay.com 7 SiP12202 Vishay Siliconix APPLICATION NOTES Inductor Selection: An inductor is one of the energy storage component in a converter. Choosing an inductor means specifying its size, structure, material, inductance, saturation level, dc-resistance (DR.), and core loss. Fortunately, there are many inductor vendors that offer wide selections with ample specifications and test data, such as Vishay Dale. The following are some key parameters that users should focus on. In PWM mode, inductance has a direct impact on the ripple current. The peak-to-peak inductor ripple current can be calculated as IP - P = where f = switching frequency. Higher inductance means lower ripple current, lower current, lower voltage ripple on both input and output, and higher efficiency, unless the resistive loss of the inductor dominates the overall conduction loss. However, higher inductance also means a bigger inductor size and a slower response to transients. In PSM mode, inductance affects inductor peak current, and consequently impacts the load capability and switching frequency. For fixed line and load conditions, higher inductance results in a lower peak current for each pulse, a lower load capability, and a higher switching frequency. The saturation level is another important parameter in choosing inductors. Note that the saturation levels specified in data sheets are maximum currents. For a dc-todc converter operating in PWM mode, it is the maximum peak inductor current that is relevant, and which can be calculated using these equations: I PK = I OUT + IP - VOUT I RMS = I LOAD(m ax) VIN 1 VOUT VIN It is common practice to rate for the worst-case RMS ripple that occurs when the duty cycle is at 50%: I RMS = VOUT (VIN - V OUT) VIN Lf I LOAD(max) 2 Output Capacitor Selection: The selection of the output capacitor is primarily determined by the ESR required to minimize voltage ripple and current ripple. The desired output ripple VOUT can be calculated by: VOUT = (I max - Imin ) ESR + 1 8fCOUT Current ripple can be calculated by: (I max ) - I min = T VOUT L VIN ( VIN - VOUT ) Where: VOUT = Desired Output Ripple Voltage f = switching frequency Imax = Maximum Inductor Current Imin = Minimum Inductor Current T = Switching Period Multiple capacitors placed in parallel may be needed to meet the ESR requirements. However if the ESR is too low it can cause instability. P 2 This peak current varies with inductance tolerance and other errors, and the rated saturation level varies over temperature. So a sufficient design margin is required when choosing current ratings. A high-frequency core material, such as ferrite, should be chosen, the core loss could lead to serious efficiency penalties. The DCR should be kept as low as possible to reduce conduction losses. www.vishay.com 8 Input Capacitor Selection: To minimize current pulse induced ripple caused by the step-down controller and interference of large voltage spikes from other circuits, a low-ESR input capacitor is required to filter the input voltage. The input capacitor should be rated for the maximum RMS input current: MOSFET Selection: The key selection criteria for the MOSFETs include maximum specifications for on-resistance, drain-source voltage, gate source, current, and total gate charge Qg. While the voltage ratings are fairly straightforward, it is important to carefully balance on-resistance and gate charge. In typical MOSFETs, the lower the on-resistance, the higher the gate charge. The power loss of a MOSFET consists of conduction, gate charge, and crossover losses. For lower-current application, gate charge losses become a significant factor, so low gate charge MOSFETs, such as Vishay Siliconix's LITTLE FOOT family of PWM-optimized devices, are desirable. Document Number: 73542 S-52332-Rev. B, 07-Nov-05 SiP12202 Vishay Siliconix Compensation: VIN VOUT R1 FB Compensation L GM R2 VOUT PWM Comp R3 C2 0.6 V COUT C1 ESR OSC 500 kHz Vosc The SiP12202 uses voltage mode control in conjunction with a high frequency Transconductance error amplifier. The voltage feedback loop is compensated at the Comp/ SD pin, which is the output node of the error amplifier. The feedback loop is generally compensated with an RC + C (one pole, one zero) network from comp to GND. Loop stability is affected by the values of the inductor, the output capacitor, the output capacitor ESR, and the error amplifier compensation network. The ideal Bode plot for a compensated system would be gain that rolls off at a slope of - 20 dB/decade, crossing 0 dB at the desired bandwidth and a phase margin greater than 90 for all frequencies below the 0 dB crossing. The compensation network used with the error amplifier must provide enough phase margin at the 0 dB crossover frequency for the overall open-loop transfer function to be stable. The following guidelines will calculate the compensation pole and zero to stabilize the SiP12201. The inductor and output capacitor values are usually determined by efficiency, voltage and current ripple requirements. The inductor and the output capacitor create a double pole at the frequency and a -180 phase change: f p(LC) = 1 2 L C OUT The ESR of the output capacitor and the output capacitor value form a zero at the frequency: f Z(ESR) = Document Number: 73542 S-52332-Rev. B, 07-Nov-05 1 2 (ESR)(C OUT ) The fZ(ESR) typically should be higher than the fp(LC) and give a 90 phase boost. R3 and C1 will establish the second zero of the system. The frequency of the zero should be 2 x lower than the double pole frequency of the inductor and the output capacitor. f Z(comp) = 1 2 R3C1 Choose a value for R3 usually between 1 k and 10 k. This second zero will provide the second 90 phase boost and will stabilize the closed loop system. The second pole should be placed at 1/2 the switching frequency. f p(comp) = 1 2 R3 C2 Although a mathematical approach to frequency compensation can be used, the added complication of input and/or output filters, unknown capacitor ESR, and gross operating point changes with input voltage, load current variations, all suggest a more practical empirical method. This can be done by injecting at the load a variable frequency small signal voltage between the output and the feedback network and using an RC network box to iterate toward the final values; or by obtaining the optimum loop response using a network analyzer to measure the loop Gain and Phase. Layout: As in the design of any switching dc-to-dc converter, driver careful layout will ensure that there is a successful transition from design to production. One of the few drawbacks of switching dc-to-dc converters is the noise induced by their high-frequency switching. Parasitic inductance and capacitance may become significant when a converter is switching at 500 kHz. However, www.vishay.com 9 SiP12202 Vishay Siliconix noise levels can be minimized by properly laying out the components. Here are some general guidelines for laying out a step-down converter with the SiP12202. Since power traces in step down converters carry pulsating current, energy stored in trace inductance during the pulse can cause high-frequency ringing with input and output capacitors. Minimizing the length of the power traces will minimize the parasitic inductance in the trace. The same pulsating currents can cause voltage drops due to the trace resistance and cause effects such as ground bounce. Increasing the width of the power trace, which in-creases the cross sectional area, will minimize the trace resistance. In all dc-to-dc converters the decoupling capacitors should be placed as close as possible to the pins being decoupled to reduce the noise. The connections to both terminals should be as short as possible with low-inductance (wide) traces. In the SiP12202 converters, the VIN is decoupled to PGND. It may be necessary to decouple VDD to AGND, with the decoupling capacitor being placed adjacent to the pins. AGND and PGND traces should be isolated from each other and only connected at a single node such as a "star ground". www.vishay.com 10 Document Number: 73542 S-52332-Rev. B, 07-Nov-05 Legal Disclaimer Notice Vishay Disclaimer All product specifications and data are subject to change without notice. Vishay Intertechnology, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf (collectively, "Vishay"), disclaim any and all liability for any errors, inaccuracies or incompleteness contained herein or in any other disclosure relating to any product. Vishay disclaims any and all liability arising out of the use or application of any product described herein or of any information provided herein to the maximum extent permitted by law. The product specifications do not expand or otherwise modify Vishay's terms and conditions of purchase, including but not limited to the warranty expressed therein, which apply to these products. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay. The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications unless otherwise expressly indicated. Customers using or selling Vishay products not expressly indicated for use in such applications do so entirely at their own risk and agree to fully indemnify Vishay for any damages arising or resulting from such use or sale. Please contact authorized Vishay personnel to obtain written terms and conditions regarding products designed for such applications. Product names and markings noted herein may be trademarks of their respective owners. Document Number: 91000 Revision: 18-Jul-08 www.vishay.com 1