SP6127 High-Voltage, Step-Down Controller in TSOT6 FEATURES Wide 4.5V – 29V Input Voltage Range Internal compensation Built-in High-Current PMOS Driver Adjustable Overcurrent Protection Internal soft start 900kHz Constant Frequency Operation 0.6V Reference Voltage 1% output setpoint accuracy Lead Free, RoHS Compliant Package: Small 6-pin TSOT LX GND FB 6 5 4 SP6127 6 PinTSOT 1 VIN 2 GATE 3 VDR __________________________________________________________ DESCRIPTION The SP6127 is a PWM controlled step down (buck) voltage mode regulator with VIN feedforward and internal Type-II compensation. It operates from 4.5V to 29V VIN, making it suitable for 5V, 12V and 24V applications. By using a PMOS driver, this device is capable of operating at 100% duty cycle. The highside driver is designed to drive the gate 5V below VIN. The programmable overcurrent protection is based on the high-side MOSFET’s ON resistance sensing and allows setting the overcurrent protection value up to 300mV threshold (measured between VIN-LX). The SP6127 is available in a space-saving 6pin TSOT package making it the smallest controller available capable of operating from 24VDC supplies. _______________________________________ TYPICAL APPLICATION CIRCUIT VIN C1 4.7uF Q1 Si2343DS 12V 2 1 Gate GND Vin L1, IHLP-2525CZ 3.3uH, 30mOhm, 6A Rs=1k VOUT LX C7 0.1uF 6 SP6127 Ds MBRA340T3G 3 C4 22uF RZ 2K VDR 1.8V 0-2.0A R1 200k, 1% CZ 33pF 4 GND VFB GND R2 100k, 1% 5 D1 1N4148 SHDN High=Of f June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 1 2007 Sipex Corporation ABSOLUTE MAXIMUM RATINGS Input Voltage….................................................-0.3V to 30V Lx………………………………………………….…-2V to 30V FB……………..................................................-0.3V to 5.5V Storage Temperature..………………...……-65 °C to 150 °C Junction Temperature...................................-40°C to 125°C Lead Temperature (Soldering, 10 sec)…..…………..300 °C ESD Rating………..….…1kV LX, 2kV all other nodes, HBM 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. ____________________________________________ ELECTRICAL SPECIFICATIONS Specifications are for TAMB=TJ=25°C, and those denoted by ♦ apply over the full operating range, -40°C< Tj <125°C. Unless otherwise specified: VIN =4.5V to 29V, CIN = 4.7µF. PARAMETER TYP MAX UVLO Turn-On Threshold 4.2 4.35 4.5 V 0°C< Tj <125°C UVLO Turn-Off Threshold 4.0 4.15 4.4 V 0°C< Tj <125°C UVLO Hysteresis 0.2 UNITS ♦ MIN V Operating Input Voltage Range 4.5 29 V Operating Input Voltage Range 7 29 V Operating VCC Current Reference Voltage Accuracy 0.3 0.5 3 1 mA % Reference Voltage Accuracy 0.5 2 % Reference Voltage 0.594 0.6 0.606 V Reference Voltage 0.588 0.6 0.612 V 750 900 VIN/5 1050 kHz V 40 100 ns 0 % % Switching Frequency Peak-to-peak ramp Voltage Minimum ON-Pulse Duration Minimum Duty Cycle Maximum Duty Cycle 100 Gate Driver Turn-Off Resistance 50 60 kΩ Gate Driver Pull-Down Resistance 4 8 Ω Gate Driver Pull-up Resistance 3 6 Ω 5.5 V VIN - VDR voltage difference 4.5 Overcurrent Threshold LX pin Input Current OFF interval during hiccup 270 25 300 30 70 330 35 mV uA ms 3 5 9 ms 1.0 1.2 Soft start time SHDN Threshold SHDN Threshold Hysteresis June 26, 2007 0.8 100 CONDITIONS V 0°C< Tj <125°C ♦ VFB=1.2V ♦ ♦ ♦ Internal resistor between GATE and VIN VIN=12V, VFB=0.5V, Measure resistance between GATE and VDR VIN=12V, VFB=0.7V, Measure resistance between GATE and VIN ♦ Measure VIN – VDR, VIN>7V Measure VIN - LX VLX = VIN VFB=0.58V, measure between VIN=4.5V and first GATE pulse ♦ Apply voltage to FB mV SP6127 TSOT-6 PFET Buck Controller Page 2 2007 Sipex Corporation _______________________________________________________ PIN DESCRIPTION PIN # PIN NAME 1 VIN 2 GATE 3 VDR 4 FB 5 GND 6 LX DESCRIPTION Input power supply for the controller. Place input decoupling capacitor as close as possible to this pin. Connect to the gate terminal of the external P-channel MOSFET. Power supply for the internal driver. This voltage is internally regulated to about 5V below VIN. Place a 0.1µF decoupling capacitor between VDR and VIN as close as possible to the IC. Regulator feedback input. Connect to a resistive voltage-divider network to set the output voltage. This pin can be also used for ON/OFF control. If this pin is pulled above 1V the P-channel driver is disabled and controller resets internal soft start circuit. Ground pin. This pin is used as a current limit input for the internal current limit comparator. Connect to the drain pin of the external MOSFET through an optional resistor. Internal threshold is pre-set to 300mV nominal and can be decreased by changing the external resistor based on the following formula: VTRSHLD = 300mV – 30uA * R ______________________________________________________ BLOCK DIAGRAM VIN 5V VDR Oscillator Vin - 5V LDO VIN 5V Internal LDO I = k x VIN FAULT PWM Latch Reset Dominant VREF GATE S + FB R + - PWM Comparator Error Amplifier VDR FAULT FAULT ENBL LX - 70ms delay + - 1V June 26, 2007 FAULT Register S R R + UVLO 4-Bit counter Overcurrent Comparator 30uA VIN - 0.3V GND POR Set Dominant SP6127 TSOT-6 PFET Buck Controller Page 3 2007 Sipex Corporation ____________________________________________________ GENERAL OVERVIEW The SP6127 is a fixed frequency, Voltage-mode, non-synchronous PWM controller optimized for minimum component, small form factor and cost effectiveness. It has been designed for singlesupply operation ranging from 4.5V to 29V. SP6127 has Type-II internal compensation for use with Electrolytic/Tantalum output capacitors. For ceramic capacitors Type-III compensation can be implemented by simply adding an R and C between output and Feedback. A precision 0.6V reference, present on the positive terminal of the Error Amplifier, permits programming of the output voltage down to 0.6V via the FB pin. The output of the Error Amplifier is internally compared to a feed-forward (VIN/5 peak-to-peak) ramp and generates the PWM control. Timing is governed by an internal oscillator that sets the PWM frequency at 900kHz. SP6127 contains useful protection features. Overcurrent protection is based on the high-side MOSFET’s RDS(ON) and is programmable via a resistor placed at LX node. Under-Voltage LockOut (UVLO) ensures that the controller starts functioning only when sufficient voltage exists for powering IC’s internal circuitry. SP6127 Loop Compensation where: f ESRZERO = f DBPOLE = 1 2.π .R ESR .C OUT 1 2.π . L ⋅ C OUT ……….. (2) ………… (3) Creating a Type-III compensation Network The above condition requires the ESR zero to be at a lower frequency than the double-pole from the LC filter. If this condition is not met, Type-III compensation should be used and can be accomplished by placing a series RC combination in parallel with R1 as shown below. The value of CZ can be calculated as follows and RZ selected from table 1. CZ = The SP6127 includes Type-II internal compensation components for loop compensation. External compensation components are not required for systems with tantalum or aluminum electrolytic output capacitors with sufficiently high ESR. Use the condition below as a guideline to determine whether or not the internal compensation is sufficient for your design. Type-II internal compensation is sufficient if the following condition is met: L ⋅C ………….. (4) 1.25 × R1 fESRZERO/ fDBPOLE 1X 2X 3X 5X >= 10X RZ 50KΩ 40KΩ 30KΩ 10KΩ 2KΩ f ESRZERO < f DBPOLE ………………. (1) Table1- Selection of RZ June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 4 2007 Sipex Corporation ______________________________________________________ GENERAL OVERVIEW Vout SP6127 CP1 2pF RZ CZ2 130pF RZ2 200k CZ R1 200k, 1% VFB + Vref =0.6V R2 Error Amplif ier Figure 1- RZ and CZ in conjunction with internal compensation components form a TypeIII compensation network Loop Compensation Example 1- A converter utilizing a SP6127 has a 3.3µH inductor and a 22µF/5mΩ ceramic capacitor. Determine whether Type-III compensation is needed. From equation (2) fESRZERO = 1.45MHz. From equation (3) fDBPOLE = 18.4 kHz. Since the condition specified in (1) is not met, Type-III compensation must be used by adding external components RZ and CZ. Using equation (4) CZ is calculated to be 34pF (use 33pF). Following the guideline given in table 1, a 2kΩ RZ should be used. The steps followed in example 1 were used to compensate the typical application circuit shown on page 1. Satisfactory frequency response of the circuit, seen in figure 2, validates the above procedure. Loop Compensation Example 2- A converter utilizing the SP6127 has a 3.3µH inductor and a 220µF, 82mΩ Aluminum Electrolytic capacitor. Determine whether Type-III compensation is needed. From equation (2) fESRZERO = 8.8kHz. From equation (3) fDBPOLE = 5.9kHz. Since the condition specified in (1) is not met, Type-III compensation needs to be used by adding external components RZ and CZ. Using equation (4) CZ is calculated 108pF (use 100 pF). Since fESRZERO /fDBPOLE is approximately 2, RZ must be set at 40kΩ. Figure 2- Satisfactory frequency response of typical application circuit shown on page 1. Crossover frequency fc is 100kHz with a corresponding phase margin of 60 degrees. June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 5 2007 Sipex Corporation ______________________________________________________ GENERAL OVERVIEW for Rs in the range of 0.5kΩ to 3kΩ. For Rs larger than 3kΩ, test results are lower than those predicted by (5), due to circuit parasitics. Therefore the maximum value of Rs should be limited to 3kΩ. Overcurrent Protection (OCP) Vin SP6127 Gate Q1 Ov er-Current Comparator LX Rs + Ds 30uA Vin - 0.3V Note that in order to safeguard against false overcurrent trigger due to transients, there is a 150ns delay between the turn on of the MOSFET and when OCP circuit is activated. As a consequence at very high Vo/VIN ratio, where MOSFET on-time is less than 150ns, the OCP circuit will not detect overcurrent. Using the ON/OFF Function Figure 3 Overcurrent protection circuit The overcurrent protection (OCP) circuit functions by monitoring the voltage across the high-side FET Q1. When this voltage exceeds 0.3V, the overcurrent comparator triggers and the controller enters hiccup mode. For example if Q1 has RDS(ON)=0.1Ω, then the overcurrent will trigger at I = 0.3V/0.1Ω=3A. To program a lower overcurrent use a resistor Rs as shown in figure 1. Calculate Rs from: Rs = 0.3 − (1.15 × Iout × Rds (on) × Kt ) ...(5) 30uA The Feedback pin serves a dual role of ON/OFF control. The MOSFET driver is disabled when a voltage greater than 1V is applied at the FB pin. Maximum voltage rating of this pin is 5.5V. The controlling signal should be applied through a small signal diode as shown on page 1. Please note that an optional 10kΩ bleeding resistor across the output helps keep the output capacitor discharged under no load condition. Programming the Output Voltage To program the output voltage, calculate R2 using the following equation: Where: R2 = 1.15 is used to calculate peak inductor current which is nominally 15% higher than average output current RDS(ON) is MOSFET ON-resistance rating Kt is a multiplier that accounts for increase in RDS(ON) due to temperature Example: A switching MOSFET used with SP6127 has RDS(ON) of 0.08Ω and Kt is 1.5. Program the over-current circuit so that maximum output is 2A. Rs = 0.3 − (1.15 × 2 A × 0.08Ohm × 1.5) 30uA Rs=800Ω Using the above equation there is good agreement between calculated and test results June 26, 2007 R1 Vout − 1 Vref Where: VREF=0.6 is the reference voltage of the SP6127 R1=200kΩ is a fixed-value resistor that, in addition to being a voltage divider, it is part of the compensation network. In order to simplify compensation calculations, R1 is fixed at 200kΩ. Soft Start Soft Start is preset internally to 5ms (nominal). Internal Soft Start eliminates the need for the external capacitor CSS that is commonly used to program this function. SP6127 TSOT-6 PFET Buck Controller Page 6 2007 Sipex Corporation ______________________________________________________ GENERAL OVERVIEW MOSFET Gate Drive The P-channel drive is derived through an internal regulator that generates VIN-5V. This pin (VDR) must be connected to VIN with a 0.1µF decoupling capacitor. The gate drive circuit swings between VIN and VIN-5 and employs powerful drivers for efficient switching of the Pchannel MOSFET. voltage selection. For a low duty cycle application such as the circuit shown on first page, the Schottky diode is conducting most of the time and its conduction losses are the largest component of losses in the converter. Conduction losses can be estimated from: Vout Pc = Vf × Iout × 1 − Vin where: VF is diode forward voltage at IOUT Power MOSFET Selection Select the Power MOSFET for Voltage rating BVDSS, On resistance RDS(ON), and thermal resistance RTHJA. BVDSS should be about twice as high as VIN in order to guard against switching transients. The recommended MOSFET voltage rating for VIN of 5V, 12V and 24V is 12V, 30V and 40V respectively. RDS(ON) must be selected such that when operating at peak current and junction temperature, the Overcurrent threshold of the SP6127 is not exceeded. Allowing 50% for temperature coefficient of RDS(ON) and 15% for inductor current ripple, the following expression can be used: 0.3V RDS (ON ) ≤ 1.5 × 1.15 × Iout Within this constraint, selecting MOSFETs with lower RDS(ON) will reduce conduction losses at the expense of increased switching losses. As a rule of thumb, select the highest RDS(ON) MOSFET that meets the above criteria. Switching losses can be assumed to roughly equal to the conduction losses. A simplified expression for conduction losses is given by: Vout Pcond = Iout 2 × RDS (ON ) × Vin The MOSFET’s junction temperature can be estimated from: T = (2 × Pc × Rthja ) + Tambient Schottky Rectifier selection The Schottky diode’s AC losses due to its switching capacitance are negligible. Inductor Selection Select the Inductor for inductance L and saturation current ISAT. Select an inductor with ISAT higher than the programmed overcurrent. Calculate inductance from: Vout 1 1 L = (Vin − Vout ) × × × Vin f Irip where: VIN is converter input voltage VOUT is converter output voltage f is switching frequency IRIP is inductor peak-to-peak current ripple (nominally set to 30% of IOUT) Keep in mind that a higher IRIP results in a smaller inductor which has the advantages of small size, low DC equivalent resistance DCR, high saturation current ISAT and allows the use of a lower output capacitance to meet a given step load transient. A higher IRIP, however, increases the output voltage ripple and increases the current at which converter enters Discontinuous Conduction Mode. The output current at which converter enters DCM is ½ of IRIP. Note that a negative current step load that drives the converter into DCM will result in a large output voltage transient. Therefore the lowest current for a step load should be larger than ½ of IRIP. Select the Schottky Diode for Voltage rating VR, Forward voltage Vf, and thermal resistance RTHJA. The Voltage rating should be selected using the same guidelines outlined for MOSFET June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 7 2007 Sipex Corporation ______________________________________________________ GENERAL OVERVIEW Output Capacitor Selection Note that a smaller inductor results in a higher Select the output capacitor for voltage rating, capacitance and Equivalent Series Resistance (ESR). Nominally the voltage rating is selected to be twice as large as the output voltage. Select the capacitance to satisfy the specification for output voltage overshoot/undershoot caused by current step load. A steady-state output current IOUT corresponds to inductor stored energy of ½ L IOUT2. A sudden decrease in IOUT forces the energy surplus in L to be absorbed by COUT. This causes an overshoot in output voltage that is corrected by the reduced duty cycle of the power switch. Use the following equation to calculate COUT: IRIP, therefore requiring a larger COUT and/or lower ESR in order to meet VRIP. I 2 − I1 Cout = L × 2 2 Vos - Vout In general, total input voltage ripple should be kept below 1.5% of VIN (not to exceed 180mV). Input voltage ripple has three components: ESR and ESL cause a step voltage drop upon turn on of the MOSFET. During on time, the capacitor discharges linearly as it supplies IOUT-IIN. The contribution to Input voltage ripple by each term can be calculated from: Where: L is the output inductance I2 is the step load high current I1 is the step load low current Vos is output voltage including overshoot VOUT is steady state output voltage Select ESR such that output voltage ripple (VRIP) specification is met. There are two components to VRIP: The first component arises from charge transferred to and from COUT during each cycle. The second component of VRIP is due to inductor ripple current flowing through the output capacitor’s ESR. It can be calculated from: 1 Vrip = Irip × ESR + 8 × Cout × fs Where: IRIP is inductor ripple current fs is switching frequency COUT is output capacitor calculated above June 26, 2007 Select the input capacitor for Voltage, Capacitance, ripple current, ESR and ESL. Voltage rating is nominally selected to be twice the input voltage. The RMS value of the input capacitor current, assuming a low inductor ripple current (IRIP), can be calculated from: Icin = Iout × D(1 − D ) ∆V , Cin = Output voltage undershoot calculation is more complicated. Test results for SP6127 buck circuits show that undershoot is approximately equal to overshoot. Therefore the above equation provides a satisfactory method for calculating COUT. 2 Input Capacitor Selection 2 Iout × Vout × (Vin − Vout ) fs × Cin × Vin 2 ∆V , ESR = ESR(Iout − 0.5Irip ) ∆V , ESL = ESL (Iout − 0.5Irip ) Trise Where TRISE is the rise time of current through capacitor Total input voltage ripple is sum of the above: ∆V , Tot = ∆V , Cin + ∆V , ESR + ∆V , ESL In circuits where converter input voltage is applied via a mechanical switch, excessive ringing may be present at turn-on that may interfere with smooth startup of the SP6127. The addition of an inexpensive 100µF Aluminum Electrolytic capacitor at the input will help reduce ringing and restore a smooth startup. SP6127 TSOT-6 PFET Buck Controller Page 8 2007 Sipex Corporation _____________________________________ TYPICAL PERFORMANCE CHARACTERISTICS VIN C1 4.7uF Q1 Si2343DS 12V 2 1 Gate GND Vin L1, IHLP-2525CZ 3.3uH, 30mOhm, 6A Rs=1k VOUT LX C7 0.1uF 6 SP6127 Ds MBRA340T3G 3 C4 22uF RZ 2K VDR 1.8V 0-2.0A R1 200k, 1% CZ 33pF 4 GND VFB GND R2 100k, 1% 5 D1 1N4148 SHDN High=Of f Figure 4- Application circuit SP6127 Efficiency versus Iout, Vin=12V,Ta=25C SP6127 Load Regulation Vin=12V 90 1.810 80 1.805 Vout (V) Efficiency (%) Vout=1.8V 70 60 1.800 1.795 50 1.790 0.0 0.5 1.0 1.5 2.0 0.0 0.5 Iout (A) 1.5 2.0 Iout (A) Figure 5- Efficiency, natural convection June 26, 2007 1.0 Figure 6- Load regulation SP6127 TSOT-6 PFET Buck Controller Page 9 2007 Sipex Corporation _____________________________________ TYPICAL PERFORMANCE CHARACTERISTICS Figure 7- Step load 1-2A ch1: VIN ch2: VOUT, ch3: IOUT Figure 8- Overcurrent shutdown ch1: VIN, ch2: VOUT, ch3: Inductor current, ch4: IOUT Figure 9- Startup no load ch1: VIN, ch2: VOUT, ch3: IOUT Figure 10- Start up 2A ch1: VIN ch2: VOUT, ch3: IOUT Figure 11- Output ripple at 0A is 32mV ch1: VIN, ch2: VOUT, ch3: IOUT June 26, 2007 Figure 12- Output ripple at 2A is 12mV ch1: VIN, ch2: VOUT, ch3: IOUT SP6127 TSOT-6 PFET Buck Controller Page 10 2007 Sipex Corporation ______________________________________________________ PACKAGE: 6PIN TSOT June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 11 2007 Sipex Corporation Ordering Information: Part Number Temperature Range Package SP6127EK1-L………………………...……….-40°C to +125°C……………….………………..6 Pin TSOT SP6127EK1-L/TR………………………….....-40°C to +125°C…….…………….………….....6 Pin TSOT For further assistance: Email: WWW Support page: Sipex Application Notes: [email protected] http://www.sipex.com/content.aspx?p=support http://www.sipex.com/applicationNotes.aspx Sipex Corporation Solved by TM Headquarters and Sales Office 233 South Hillview Drive Milpitas, CA95035 tel: (408) 934-7500 FAX: (408) 935-7600 Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others. June 26, 2007 SP6127 TSOT-6 PFET Buck Controller Page 12 2007 Sipex Corporation