SC410 3A EcoSpeed® Step-Down Regulator with LDO and Ultrasonic Power Save POWER MANAGEMENT Features Description Input voltage — 5.5V to 24V Output voltage — 0.75V to 7.5V Output current — Up to 3A Internal reference — + 1% Small ceramic capacitors Power good pin (open-drain) Adaptive on-time control: Excellent transient response Programmable pseudo-fixed frequency during CCM Fault protection features: Cycle-by-cycle current limit Short circuit protection Over and under output voltage protection Over-temperature Internal soft-start Ultrasonic power save and smart PSAVE Internal LDO for bias voltage Ultra-small lead-free 3 x 3mm, 10-Pin MLPD package WEEE and RoHS compliant • • • • • • Applications The SC410 is an integrated, synchronous 3A EcoSpeed® step-down regulator. It incorporates Semtech’s advanced, patented adaptive on-time architecture to achieve bestin-class dynamic performance using point-of-load applications. The input voltage range is 5.5V to 24V with a programmable output voltage from 0.75V up to 7.5V. The device features an internal LDO and ultrasonic PSAVE mode for high efficiency across the output load range. Adaptive on-time control provides programmable pseudo-fixed frequency operation in continuous conduction and excellent transient performance. The switching frequency can be set from 200kHz to 1MHz, allowing the designer to reduce external LC filtering and minimize light load (standby) losses. Additional features include cycle-by-cycle current limit, soft start, input UVLO and output OV protection, and over temperature protection. The open-drain PGOOD pin provides output status. Standby current is less than 10μA when disabled. The device is available in a low profile, thermally enhanced MLPD 3 x 3mm 10-pin package. Networking Equipment, Embedded Systems Medical Equipment, Office Automation Instrumentation, Portable Systems Consumer Devices such as DTV and Set-top Boxes POL Converters Typical Application Circuit Enable EN SC410 PGOOD PGOOD CBST VIN VIN TON CIN LX VOUT L1 COUT RTON CLDO2 RTOP LDO CLDO1 FB AGND Revision 4.0 BST PGND © 2011 Semtech Corporation RBOT SC410 Pin Configuration BST 1 VIN 2 LX Ordering Information 10 TOP VIEW LDO 9 AGND 3 8 TON PGND 4 7 EN PGOOD 5 6 FB Device Package SC410MLTRT(1)(2) MLPD-10 3 x 3 SC410EVB Evaluation Board Notes: (1) Available in tape and reel only. A reel contains 3,000 devices. (2) Lead-free packaging only. Device is WEEE and RoHS compliant and halogen-free. MLPD; 3 x 3, 10 LEAD θJA = 40°C/W Marking Information 410 yyww xxxx yyww = Date code xxxx = Lot number SC410 Absolute Maximum Ratings Recommended Operating Conditions LX to GND (V). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to +28 Supply Input Voltage (V) . . . . . . . . . . . . . . . . . . . . . . . 5.5 to 24 VIN to PGND, EN to AGND (V). . . . . . . . . . . . . . . . . -0.3 to +28 Maximum Continuous Output Current (A) . . . . . . . . . . . . . 3 VIN to LDO (V). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 0 . 3 Maximum Peak Inductor Current (A). . . . . . . . . . . . . . . . . . 5.0 BST to LX (V). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to +6.0 Thermal Information BST to PGND (V) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to +34 LDO to AGND (V) . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to +6.0 Storage Temperature (°C ). . . . . . . . . . . . . . . . . . -60 to +150 FB, PGOOD, TON (V). . . . . . . . . . . . . . . . . . . . . -0.3 to LDO +0.3 Maximum Junction Temperature (°C ). . . . . . . . . . . . . . . . 150 AGND to PGND (V). . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 to +0.3 Operating Junction Temperature (°C ). . . . . . . -40 to +125 Maximum Peak Inductor Current (A). . . . . . . . . . . . . . . . . 5 . 5 Thermal Resistance, Junction to Ambient(2) (°C/W ). . . . . 40 Peak IR Reflow Temperature (°C ). . . . . . . . . . . . . . . . . . . . . 260 ESD Protection Level (kV)(1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 Exceeding the above specifications may result in permanent damage to the device or device malfunction. Operation outside of the parameters specified in the Electrical Characteristics section is not recommended. NOTES: (1) Tested according to JEDEC standard JESD22-A114-B. (2) Calculated from package in still air, mounted to 3 x 4.5 (in), 4 layer FR4 PCB with thermal vias under the exposed pad per JESD51 standards. Electrical Characteristics Unless specified: VIN =12V, TA=+25°C for Typ, -40°C to +85°C for Min and Max, TJ < 125°C, per detailed application circuit Parameter Conditions Min Typ Max Units Input Supplies VIN UVLO Threshold Programmable with EN pin after 2 switching cycles 1.5 V 50 mV 4 V 0.3 V VEN = 0V 9 μA IOUT= 0A, fSW=25kHz(1) 2.5 mA VIN UVLO Hysteresis Internal Bias UVLO Threshold Rising UVLO V TH Internal Bias UVLO Hysteresis VIN Supply Current Controller FB On-Time Threshold Frequency Programming Range 0.7425 See RTON Calculation Minimum Frequency during Ultrasonic PSAVE FB Input Bias Current FB=5V or 0V 0.75 200 0.7575 V 1000 kHz 22 -1 kHz +1 μA SC410 Electrical Characteristics (continued) Parameter Conditions Min Typ Max Units Continuous Mode VIN=15V, VOUT=3V, RTON= 200kΩ 0.9 1 1.1 μs Timing On-Time Minimum On-Time(1) 100 ns Minimum Off-Time(1) 320 ns 850 µs Soft start Soft start Time(1) Delay from PWM Switching to Output Regulation Current Sense Zero-Crossing Detector Threshold LX - PGND -10 0 +10 mV Power Good Power Good Threshold PGOOD Delay Time(1) Upper Limit, VFB > internal 750mV reference 120 Lower Limit, VFB < internal 750mV reference 90 Between VOUT at 90% of its regulation value and the PGOOD signal transitioning to high 1 ms 5 µs Noise Immunity Delay Time (1) Leakage %VREF 1 Power Good On-Resistance µA 10 Ω Fault Protection Output Under-Voltage Fault FB with Respect to REF, 8 Consecutive Switching Cycles 75 %VREF Output Over-Voltage Fault FB with Respect to REF 120 %VREF Smart PowerSave Protection Threshold FB with Respect to REF 110 %VREF 5 μs 145 °C PWM Output Enabled(1) 1.5 V LDO Output Enabled 0.8 V OV, UV Fault Noise Immunity Delay (1) Over-Temperature Shutdown (1) OT Latched Enable Logic EN Input Bias Current VEN = 5V -10 10 μA SC410 Electrical Characteristics (continued) Parameter Conditions Min Typ Max Units Gate Drivers BST Switch On resistance 25 Ω 3.2 A Internal Power MOSFETs Current Limit(2) LX Leakage Current Inductor Valley Current Limit, VLDO=5V 2.4 VIN=24V, LX=0V, High Side 1 High Side 215 Low Side 110 10 Switch Resistance µA mΩ Non-overlap time (1) 15 ns Linear Regulator (The LDO is shorted to the bias node, internally) LDO Accuracy LDO Current Limit LDO Drop Out Voltage -4 4 Short circuit protection, VIN = 12V, VLDO <80% of final VLDO value 35 Operating current limit, VIN = 12V, VLDO > 80% of final VLDO value 100 From VIN to VLDO, ILDO = 100mA 1.2 %VLDO mA V Note: (1) Typical value from EVB, not ATE tested. (2) The minimum inductor valley current limit of 2.4V gives an average output current limit of 3A assuming 1.2A inductor ripple current. SC410 Detailed Application Circuit-1 VLDO RPGOOD VIN U1 CBST VIN +5.5 to +24VDC 1 0.1μF 2 CIN(1) 3 10µF 4 5 BST S C 410 LDO AGND VIN TON LX PGND EN PGOOD FB 10 9 CLDO2 1μF CLDO1 0.1μF REN 8 7 10nF 6 RTON 90.9kΩ VOUT L1 2.2μH RL 12.4kΩ COUT2(1) 22µF COUT3(1) 22µF 3A max. CC CC_1 NP COUT1(1) 22µF CL 10nF 47pF CTOP NP RBOT 10kΩ R8 RTOP 0Ω 34kΩ Position as close to IC as possible Note: (1) Ceramic capacitors SC410 Detailed Application Circuit-2 VLDO RPGOOD VIN U1 CBST VIN +5.5 to +24VDC 1 0.1μF 2 3 CIN(1) 10µF 4 5 BST S C 410 LDO AGND VIN TON LX PGND EN PGOOD FB 10 9 CLDO1 0.1μF CLDO2 1μF REN 8 7 10nF 6 RTON 90.9kΩ VOUT L1 2.2μH COUT2(2) 3A max. CTOP NP RTOP 34kΩ RBOT 10kΩ R8 0Ω Position as close to IC as possible Notes: (1) Ceramic capacitor ( 2) Capacitor must provide sufficient ESR to provide stability for user’s application SC410 Typical Characteristics Characteristics are based on a circuit with VIN = 12V, L = 2.2µH (DCR = 35mΩ), COUT = 66µF, VOUT = 3.3V, RTON = 90.9kΩ. Load Regulation Efficiency — Power Loss VIN = 12V Efficiency 3.0 PLOSS (W) VIN = 18V 70 2.0 VIN = 24V 0 IOUT (ADC) -1.8 0.0 10.0 1.0 VIN = 12V -1.2 1.0 VIN = 12V 0.1 0.0 VIN = 8V -0.6 VIN = 8V 50 -2.4 0 0.1 Switching Frequency 0.18 VIN = 12V 0.15 400 VIN = 8V VOUT Ripple (V) 500 Frequency (kHz) 10.0 0.20 600 VIN = 24V 300 VIN = 18V 200 0.13 VIN = 18V 0.10 0.08 VIN = 24V 0.05 100 0 0.03 0.0 0.5 1.0 1.5 IOUT (ADC) 2.0 2.5 0.00 3.0 VIN = 8V VIN = 12V 0.0 0.5 IOUT = 1.5A 1.8 1.2 1 0.6 0.8 0 VOUT (%) On-Time (ms) 1.2 0.6 -1.2 0.2 -1.8 9 12 15 18 Input Voltage (V) 1.5 IOUT (ADC) 2.0 2.5 3.0 21 24 IOUT = 1.5A -0.6 0.4 6 1.0 Line Regulation On-Time vs. VIN 0 1.0 IOUT (ADC) Ripple vs. IOUT 700 1.4 VIN = 24V 0.6 PLOSS VIN = 18V 60 VIN = 18V 1.2 VIN = 24V 80 Efficiency (%) 1.8 4.0 VIN = 8V VOUT (%) 90 -2.4 6 9 12 15 18 Input Voltage (V) 21 24 SC410 Typical Characteristics (continued) Characteristics are based on a circuit with VIN = 12V, L = 2.2µH (DCR = 35mΩ), COUT = 66µF, VOUT = 3.3V, RTON = 90.9kΩ. Transient Response Power Save IOUT = 3A to 0A IOUT = 0A (20mV/div) (50mV/div) (10V/div) (10V/div) Time (100µ������ s����� /div) Time (10µ������ s����� /div) Shutdown CCM IOUT = 1.5A IOUT = 1.5A (5V/div) (5V/div) (20mV/div) (1V/div) (10V/div) (10V/div) Time (2µ������ s����� /div) Time (40µ������ s����� /div) Start-up Start-up IOUT = 0A IOUT = 1.5A (5V/div) (5V/div) (5V/div) (5V/div) (1V/div) (1V/div) (10V/div) (10V/div) Time (400µ������ s����� /div) Time (400µ������ s����� /div) SC410 Typical Characteristics (continued) Characteristics are based on a circuit with VIN = 12V, RTON = 90.9kΩ. Efficiency — Power Loss (5 VOUT) Efficiency — Power Loss (3.3 VOUT) 4 90 80 3 70 2 60 50 PLOSS 0.001 0.01 0.1 IOUT (ADC) 1 10 VOUT = 5V, L= 4.7µH (16.2mΩ), CC = 220pF, COUT = 44µF 5 Efficiency 4 80 3 70 2 1 60 0 50 0.001 1 PLOSS 0.01 0.1 IOUT (ADC) 1 PLOSS (W) Efficiency 100 Efficiency (%) Efficiency (%) 90 5 PLOSS (W) VOUT = 3.3V, L= 3.3µH (28mΩ), CC = 270pF, COUT = 66µF 100 10 0 Pin Descriptions Pin # Pin Name Pin Function 1 BST Bootstrap pin — A capacitor is connected between BST and LX to develop the floating voltage for the high-side gate drive. 2 VIN Power input supply voltage 3 LX Switching (phase) node 4 PGND 5 PGOOD 6 FB Feedback input for switching regulator — Connect to an external resistor divider from the output to program the output voltage. 7 EN Enable input for switching regulator —Pull EN high to enable the part with ultrasonic power save mode enabled. Connect to AGND to disable the switching regulator. A voltage divider can be added between VIN and AGND pins for input UVLO functionality. 8 TON 9 AGND 10 LDO Output for the internal LDO and internal connection to the bias node — Decoupling capacitors are required to AGND and PGND regardless of the use of the LDO for external loads. PAD Thermal pad for heatsinking purposes. (Not connected internally) Connect to AGND plane using multiple vias. Power ground Open-drain power good indicator — High impedance indicates power is good. An external pull-up resistor is required. On-time set input — Set the on-time by connecting a series resistor to AGND. Analog Ground. 10 SC410 Block Diagram AGND 9 PGOOD EN BST 5 7 1 LDO LDO FB Reference Control and Status 2 VIN 3 LX 4 PGND Soft Start LX FB On-Time Generator 6 Gate Drive Control LDO FB Comparator TON 8 Zero Cross Detector RILIM VIN Valley Current Limit ILIM 5V LDO LDO 10 LDO 11 SC410 Applications Information Synchronous Buck Converter The SC410 is a step down synchronous buck DC-DC regulator. The device is capable of 3A operation at very high efficiency in a tiny 3 x 3-10 pin package. The programmable operating frequency range of 200kHz – 1MHz enables the user to optimize the design for minimum board space and optimum efficiency. The buck regulator employs pseudo-fixed frequency adaptive on-time control. This control method allows fast transient response thereby lowering the size of the power components used in the system. Input Voltage Range The SC410 can operate with a wide input voltage ranging from 5.5V to 24V. The internal LDO generates a fixed 5V output that provides power for the bias of the SC410. The LDO can also provide additional power to an external load. Psuedo-fixed Frequency Adaptive On-time Control The PWM control method used by the SC410 is pseudofixed frequency, adaptive on-time, as shown in Figure 1. The ripple voltage generated at the output capacitor ESR is divided down by the feedback resistor network and used as a PWM ramp signal. The ripple seen at the FB pin is used to trigger the on-time of the controller. TON VIN VLX CIN Q1 VFB VLX VOUT L Q2 FB Threshold ESR + FB COUT output voltage value and VIN. The period is proportional to output voltage and inversely proportional to input voltage. The value of the output voltage is obtained by filtering the voltage seen on the LX pin. With this adaptive on-time design, the device automatically anticipates the on-time needed to regulate VOUT for the present VIN condition and at the selected frequency. The advantages of adaptive on-time control are: • • • • • Predictable operating frequency during CCM compared to other variable frequency methods. Reduced component count by eliminating the error amplifier and compensation components. Reduced component count by removing the need to sense and control inductor current. Fast transient response — the response time is controlled by a fast comparator instead of a typically slow error amplifier. Reduced output capacitance due to fast transient response One-Shot Timer and Operating Frequency The one-shot timer operates as shown in Figure 2. The feedback comparator output goes high when VFB is less than the internal 750mV reference. This feeds into the gate drive and turns on the high-side MOSFET, and also starts the one-shot timer. The one-shot timer uses an internal comparator, timing capacitor, and a low pass filter (LPF) which regenerates VOUT from LX. One comparator input is connected to the filtered LX voltage, the other input is connected to the capacitor. When the on-time begins, the internal capacitor charges from zero volts through a current which is proportional to VIN. When the capacitor voltage reaches VOUT, the on-time is completed and the high-side MOSFET turns off. Figure 1 — PWM Control Method, VOUT Ripple The adaptive on-time is determined by an internal oneshot timer. When the one-shot is triggered by the feedback ripple, the device sends a single on-time pulse to the high-side MOSFET. The pulse period is determined by the 12 SC410 Applications Information (continued) FB - Ref. PWM + VIN S R VLX_FILTER One-Shot Timer VIN Q Hi-side and Lo-side Gate Drivers Q1 VOUT VLX Q2 L VOUT Voltage Selection The switcher output voltage is regulated by comparing VOUT as seen through a resistor divider at the FB pin to the internal 750mV reference voltage, see Figure 3. FB ESR COUT RTON VLX_FILTER LPF VOUT + R1 To FB pin R2 Time = K x (VOUT/VIN) Figure 2 — On-Time Generation This method automatically produces an on-time that is proportional to VOUT and inversely proportional to VIN. Under steady-state operating conditions in continuous conduction mode, the switching frequency can be determined from the on-time by the following equation. fSW VOUT t ON u VIN The SC410 uses an external resistor to set the on-time which indirectly sets the frequency. The on-time can be programmed to provide operating frequencies from 200kHz to 1MHz using a resistor between the TON pin and ground. The resistor value is selected by the following equation. R TON § V 1 ¨¨ 400: u IN 25pF f V u SW OUT © · ¸¸ u 1.2 ¹ The maximum RTON value allowed is shown by the following equation. RTON _ MAX VIN _ MIN 10 u 1.5PA Immediately after the on-time, the DL (the drive signal for the low side FET) output drives high to turn on the low-side MOSFET. DL has a minimum high time of ~320ns, after which DL continues to stay high until one of the following occurs: • • VFB falls below the 750mV reference The zero cross detector senses that the voltage on the LX node is below ground. PSAVE is activated 8 periods after the zero cross is detected. Figure 3 — Output Voltage Selection Note that this control method regulates the valley of the output ripple voltage, not the DC value. The DC output voltage VOUT is offset by the output ripple according to the following equation. VOUT § R · §V · 0.75 u ¨¨1 1 ¸¸ ¨ RIPPLE ¸ © R2 ¹ © 2 ¹ Enable Input The EN input is used to enable or disable the switching regulator. When EN is low (grounded), the switching regulator and LDO are disabled and the SC410 is in its lowest power state. When disabled, the output power switches are tri-stated. When EN is higher than 0.8V, the internal LDO will be activated. The switching regulator remains off until the voltage at the EN pin exceeds 1.5V. The EN pin can be used for implementing UVLO for the input voltage by configuring a voltage divider from VIN to EN to PGND. Continuous Mode Operation The SC410 operates in CCM (Continuous Conduction Mode) at larger load currents when the load is greater than or equal to half of the inductor ripple current (Figure 4). In this mode one of the power MOSFETs is always on, with no intentional dead time other than to avoid crossconduction. This mode of operation results in uniform frequency. 13 SC410 Applications Information (continued) FB Ripple Voltage (VFB) Minimum fSW ~ 25kHz FB threshold (750mV) FB Ripple Voltage (VFB) FB threshold (750mV) DC Load Current Inductor Current (0A) Inductor Current On-time (TON) DH on-time is triggered when VFB reaches the FB Threshold. On-time (TON) DH On-Time is triggered when VFB reaches the FB Threshold DH DH 40µsec time-out DL DL DL drives high when on-time is completed. DL remains high until VFB falls to the FB threshold. Figure 4 — Continuous Mode Operation Ultrasonic Power Save Operation The SC410 provides ultrasonic power save operation at light loads, with the minimum operating frequency fixed at 22kHz. This is accomplished using an internal timer that monitors the time between consecutive high-side gate pulses. If the time exceeds 40µs, DL drives high to turn the low-side MOSFET on. This draws current from VOUT through the inductor, forcing both VOUT and VFB to fall. When VFB drops to the 750mV threshold, the next DH on-time is triggered. After the on-time is completed the high-side MOSFET is turned off and the low-side MOSFET turns on. The low-side MOSFET remains on until the inductor current ramps down to zero, at which point the low-side MOSFET is turned off. Because the on-times are forced to occur at intervals no greater than 40µs, the frequency will not fall below ~22kHz. Figure 5 shows ultrasonic power save operation. After the 40µsec time-out, DL drives high if VFB has not reached the FB threshold. Figure 5 — Ultrasonic Power Save Operation Smart Power Save Protection Active loads may leak current from a higher voltage into the switcher output. Under light load conditions with power save enabled, this can force VOUT to slowly rise and reach the over-voltage threshold, resulting in a hard shutdown. Smart power save prevents this condition. When the FB voltage exceeds 10% above nominal (exceeds 825mV), the device immediately disables power-save, and DL drives high to turn on the low-side MOSFET. This draws current from VOUT through the inductor and causes VOUT to fall. When VFB drops back to the 750mV trip point, a normal TON switching cycle begins. This method prevents a hard OVP shutdown and also cycles energy from VOUT back to VIN. Figure 6 shows typical waveforms for the smart power save feature. 14 SC410 Applications Information (continued) VOUT drifts up to due to leakage current flowing into COUT Smart Power Save Threshold (825mV) VOUT discharges via inductor and low-side MOSFET Normal VOUT ripple FB threshold DH and DL off High-side Drive (DH) In the SC410, the valley current limit is set to 3A. This results in a peak inductor current of 3A plus the peak-to-peak ripple current. In this situation, the average (load) current through the inductor is 3A plus one-half the peak-to-peak ripple current. The internal 10μA current source is temperature compensated at 2500ppm in order to provide tracking with the RDSON. Single DH on-time pulse after DL turn-off Low-side Drive (DL) Peak Inductor Current Normal DL pulse after DH on-time pulse DL turns on when Smart PSAVE threshold is reached DL turns off when FB threshold is reached Figure 6 — Smart Power Save Current Limit Protection Inductor Current The current limiting is accomplished by using the RDSON of the lower MOSFET for current sensing. The current limit is set by an internal resistor RILIM. The resistor connects from an ILIM node to the LX node which is also the drain of the low-side MOSFET. When the low-side MOSFET is on, an internal ~10μA current flows from the ILIM Node and through the RILIM resistor, creating a voltage drop across the resistor. While the low-side MOSFET is on, the inductor current flows through it and creates a voltage across the RDSON. The voltage across the MOSFET is negative with respect to ground. If this MOSFET voltage drop exceeds the voltage across RILIM, the voltage at the ILIM node will be negative and current limit will activate. The current limit then keeps the low-side MOSFET on and will not allow another high-side on-time, until the current in the low-side MOSFET reduces enough to bring the ILIM voltage back up to zero. This method regulates the inductor valley current at the level shown by ILIM in Figure 7. IPEAK ILOAD ILIM Time The peak current through the inductor and switching FETs must be less than 5A. The only way to meet this requirement is to select the switching frequency and inductor value such that the peak inductor current is less than or equal to 5A when the trough of the inductor current is 3A. Soft start of PWM Regulator Soft start is achieved in the PWM regulator by using an internal voltage ramp as the reference for the FB comparator. The voltage ramp is generated using an internal charge pump which drives the reference from zero to 750mV in ~1.8mV increments, using an internal ~500kHz oscillator. When the ramp voltage reaches 750mV, the ramp is ignored and the FB comparator switches over to a fixed 750mV threshold. During soft start the output voltage tracks the internal ramp, which limits the start-up inrush current and provides a controlled soft start profile for a wide range of applications. Typical soft start ramp time is 850μs. During soft start the regulator turns off the low-side MOSFET on any cycle if the inductor current falls to zero. This prevents negative inductor current, allowing the device to start into a pre-biased output. Power Good Output The PGOOD (power good) output is an open-drain output which requires a pull-up resistor. When the output voltage is 10% below the nominal voltage, PGOOD is pulled low. It is held low until the output voltage returns to the nominal voltage. PGOOD is held low during soft start and activated approximately 1ms after VOUT reaches regulation. Figure 7 — Valley Current Limit 15 SC410 Applications Information (continued) PGOOD will transition low if the VFB pin exceeds +20% of nominal, which is also the over-voltage shutdown threshold (900mV). Output Over-Voltage Protection OVP (Over-Voltage Protection) becomes active as soon as the device is enabled. The threshold is set at 750mV + 20% (900mV). When VFB exceeds the OVP threshold, the output goes to a tri-state with both FETs disabled and the part is latched off. There is a 5μs delay built into the OVP detector to prevent false transitions. PGOOD is also low after an OVP event. While the EN pin is above 0.5V, the LDO will be activated. While the VLDO output voltage remains below 4V (80% of the final LDO voltage), the LDO short-cicuit protection is enabled and limits the current to about 35mA. After the VLDO exceeds 4.0V (80% of VLDO Final), then the LDO operates in its normal regulation mode where the current is limited to about 100mA (see Figure 8). VLDO Final Voltage regulating with ~100mA current limit 80% of VLDO Final Output Under-Voltage Protection When V FB falls to 75% of its nominal voltage (falls to 562.5mV) for eight consecutive clock cycles, the switcher is shut off and the DH and DL drives are pulled low to turn off the MOSFETs. The controller stays off until EN is toggled or VIN is cycled. Over-Temperature Protection If the temperature rises to 145°C the device will latch off. The device can be reactivated after the temperature is reduced below 145°C by cycling the EN pin. VLDO UVLO, and POR UVLO (Under-Voltage Lock-Out) circuitry inhibits switching and tri-states the power FETs until VLDO rises above 4.0V. An internal POR (Power-On Reset) occurs when VLDO exceeds 4.0V, which resets the fault latch and soft start counter to begin the soft start cycle. The SC410 then begins a soft start cycle. The PWM will shut off if VLDO falls below 3.7V. Internal LDO Regulator The SC410 has an internal regulator that supplies the bias voltage for the PWM controller. This LDO can also supply an additional external current for an external load through the LDO pin. When activated, the LDO checks the status of the following signals to ensure proper operation can be maintained. 1. EN pin 2. VLDO output voltage 3. VIN input voltage Sort-circuit Protection @ ~35mA Figure 8 — LDO Start-Up Design Procedure When designing a switch mode supply the input voltage range, load current, switching frequency, and inductor ripple current must be specified. The maximum input voltage (VINMAX) is the highest specified input voltage. The minimum input voltage ( VINMIN) is determined by the lowest input voltage after evaluating the voltage drops due to connectors, fuses, switches, and PCB traces. The following parameters define the design. • • • • Nominal output voltage (VOUT ) Static or DC output tolerance Transient response Maximum load current (IOUT ) The two values of load current to evaluate are continuous load current and peak load current. Continuous load current relates to thermal stresses which drive the selection of the inductor and input capacitors. Peak load current determines instantaneous component stresses and filtering requirements such as inductor saturation, output capacitors, and design of the current limit circuit. 16 SC410 Applications Information (continued) The following values are used in this design example. • • • • VIN = 12V + 10% VOUT = 3.3V + 4% fSW = 500kHz Load = 3A maximum Frequency Selection Selection of the switching frequency requires making a trade-off between the size and cost of the external filter components (inductor and output capacitor) and the power conversion efficiency. The desired switching frequency is 500kHz which results from using components selected for optimum size and cost. A resistor (RTON) is used to program the on-time (indirectly setting the frequency) using the following equation. R TON § V 1 ¨¨ 400: u IN VOUT © 25pF u fSW · ¸¸ u 1.2 ¹ To select RTON, use the maximum value for VIN, and for TON use the value associated with maximum VIN. t ON V OUT V INMAX u f SW tON = 500 ns at 13.2VIN, 3.3VOUT, 500kHz Substituting for RTON results in the following solution. RTON = 78.5kΩ, use RTON = 78.7kΩ save mode when the load current decreases to 1/2 of the ripple current. For example, if ripple current is 2A then power-save operation will typically start for loads less than 1A. If ripple current is set at 40% of maximum load current, then power-save will start for loads less than 20% of maximum current. During the DH on-time, voltage across the inductor is (VIN - VOUT ). The equation for determining inductance is shown next. L ( VIN VOUT ) u t ON IRIPPLE Example In this example, the inductor ripple current is set equal to 75% of the maximum load current. Therefore ripple current will be 75% x 3A or 2.25A. To find the minimum inductance needed, use the VIN and TON values that correspond to VINMAX. L (13.2V 3.3 V ) u 501ns 2.25 A 2.204PH A standard value of 2.2µH is selected. This gives a maximum IRIPPLE of 2.53A. The peak ripple can be calculated by the equation, below where LTOL is assumed to be an inductor tolerance of 20%. IRIPPLE_PEAK = IRIPPLE_MAX x (1 + LTOL) = 2.705A Note that the inductor must be rated for the maximum DC load current plus 1/2 of the ripple current. Now, tON = 501ns given that RTON = 78.7kΩ. Inductor Selection In order to determine the inductance, the ripple current must first be defined. Low inductor values result in smaller size but create higher ripple current which can reduce efficiency. Higher inductor values will reduce the ripple current/voltage and for a given DC resistance are more efficient. However, larger inductance translates directly into larger packages and higher cost. Cost, size, output ripple, and efficiency are all used in the selection process. The ripple current under minimum VIN conditions is also checked using the following equations. The ripple current will also set the boundary for powersave operation. The switching will typically enter power- ILSAT_MIN = IRIPPLE_PEAK X 0.5 + IOUT = 4.353A t ON _ VINMIN IRIPPLE 25pF u R TON u VOUT 10ns VINMIN 611ns ( VIN VOUT ) u t ON L IRIPPLE _ VINMIN (10.8 V 3.3 V ) u 612ns 2.2PH 2.08 A 17 SC410 Applications Information (continued) Capacitor Selection The output capacitors are chosen based on required ESR and capacitance. The maximum ESR requirement is controlled by the output ripple requirement and the DC tolerance. The output voltage has a DC value that is equal to the valley of the output ripple plus 1/2 of the peak-to-peak ripple. Change in the output ripple voltage will lead to a change in DC voltage at the output. The design goal is for the output voltage regulation to be ±4% under static conditions. The internal 750mV reference tolerance is 1%. Assuming a 1% tolerance from the FB resistor divider, this allows 2% tolerance due to VOUT ripple. Since this 2% error comes from 1/2 of the ripple voltage, the allowable ripple is 4%, or 132mV for a 3.3V output. The maximum ripple current of 2.7A creates a ripple voltage across the ESR. The maximum ESR value allowed is shown by the following equations. ESRMAX 2 u VRIPPLE IRIPPLEMAX 132mV 2.705 A 1 § ·2 L1 L TOL u ¨ IOUT u IRIPPLE _ PEAK ¸ 2 © ¹ 2 1 § ·2 2.2PH 1 20%¨ 3 A u 2.705 A ¸ 2 © ¹ 2 ILPK = IMAX + 1/2 x IRIPPLEMAX ILPK = 3A + 1/2 x 2.7A = 4.353A 3.432V 3.3V 2 dlLOAD dt IMAX = maximum load release = 3A COUT ILPK u Lu 1 L TOL u ILPK I MAX u dt VOUT d lLOAD 2VPK VOUT Example dlLOAD dt 2A 1Ps This causes the output current to move from 3A to 0A in 4.8µs, giving the minimum output capacitance requirement shown in the following equation. 2 Assuming a peak voltage VPEAK of 1.150 (132mV rise upon load release), and a 6A load release, the required capacitance is shown by the next equation. COUTMIN The output capacitance is chosen to meet transient requirements. A worst-case load release, from maximum load to no load at the exact moment when inductor current is at the peak, determines the required capacitance. If the load release is instantaneous (load changes from maximum to zero in < 1µs), the output capacitor must absorb all the inductor’s stored energy. This will cause a peak voltage on the capacitor according to the following equation. VPEAK VOUT The following can be used to calculate the needed capacitance for a given dILOAD/dt. Peak inductor current is shown by the next equation. Rate of change of Load Current ESRMAX = 48.8 mΩ COUTMIN If the load release is relatively slow, the output capacitance can be reduced. At heavy loads during normal switching, when the FB pin is above the 750mV reference, the DL output is high and the low-side MOSFET is on. During this time, the voltage across the inductor is approximately VOUT. This causes a down-slope or falling di/dt in the inductor. If the load di/dt is not much faster than the di/dt in the inductor, then the inductor current will tend to track the falling load current. This will reduce the excess inductive energy that must be absorbed by the output capacitor, therefore a smaller capacitance can be used. COUT 4.353 A u 4.353 A 3 A u 1Ps 3 .3 V 2A 23.432 V 3.3 V 2.2PH1 20 % u COUT = 33µF Note that COUT is much smaller in this example, 33µF compared to 56µF based on a worst-case load release. To meet the worst case design criteria of minimum 56µF, select three capacitors rated at 22µF and 15mΩ ESR. COUTMIN = 56µF 18 SC410 Applications Information (continued) Stability Considerations Unstable operation is possible with adaptive on-time controllers, and usually takes the form of double-pulsing or ESR loop instability. Double-pulsing occurs due to switching noise seen at the FB input or because the FB ripple voltage is too low. This causes the FB comparator to trigger prematurely after the minimum off-time has expired. In extreme cases the noise can cause three or more successive on-times. Doublepulsing will result in higher ripple voltage at the output, but in most applications it will not affect operation. This form of instability can usually be avoided by providing the FB pin with a smooth, clean ripple signal that is at least 10mVp-p, which may dictate the need to increase the ESR of the output capacitors. It is also imperative to provide a proper PCB layout. An alternate method to eliminate doubling-pulsing is to add a small (~ 10pF) capacitor across the upper feedback resistor, as shown in Figure 9. This capacitor should be left unpopulated unless it can be confirmed that doublepulsing exists. Adding the CTOP capacitor will couple more ripple into FB to help eliminate the problem. An optional connection on the PCB should be provided for this capacitor. ESR Requirements A minimum ESR is required for two reasons. The first reason is to generate enough output ripple voltage to provide 10mVp-p at the FB pin (after the resistor divider) to avoid double-pulsing. The second reason is to prevent instability due to insufficient ESR. The on-time control regulates the valley of the output ripple voltage. This ripple voltage is the sum of the two voltages. One is the ripple generated by the ESR, the other is the ripple due to capacitive charging and discharging during the switching cycle. For most applications, the total output ripple voltage is dominated by the output capacitors, typically SP or POSCAP devices. For stability the ESR zero of the output capacitor should be lower than approximately one-third the switching frequency. The formula for minimum ESR is shown by the following equation. ESR MIN 3 2 u S u C OUT u f sw Using Ceramic Output Capacitors CTOP VOUT One simple method of solving this problem is to add trace resistance in the high current output path. A side effect of adding trace resistance is a decrease in load regulation. To FB pin R1 R2 Figure 9 — Capacitor Coupling to FB Pin When applications use ceramic output capacitors, the ESR is normally too small to meet the previously stated ESR criteria. In these applications it is necessary to add a small signal injection network as shown in Figure 10. In this network RL and CL filter the LX switching waveform to generate an in-phase ripple voltage comparable to the ripple seen on higher ESR capacitors. CC is a coupling capacitor used to AC couple the generated ripple onto the FB pin. ESR loop instability is caused by insufficient ESR. The details of this stability issue are discussed in the ESR Requirements section. The best method for checking stability is to apply a zero-to-full load transient and observe the output voltage ripple envelope for overshoot and ringing. Ringing for more than one cycle after the initial step is an indication that the ESR should be increased. 19 SC410 Applications Information (continued) Output Voltage Dropout L Highside RL CL R1 CC Lowside FB pin COUT R2 Figure 10 — Signal Injection Circuit The values of RL, CL, and CC are dependent on the conditions of the specific application such as VIN, VOUT, fSW and IOUT. Select a value for CL, like 10nF. Using CL, calculate RL as shown in the following equation: RL L CL u DCR Where L is the inductor value and DCR is the resistance of the inductor. The value for CC can be between CC_MIN and CC_MAX. CC _ MIN t ON REQ CC _ MAX T REQ Where T = 1/fSW and REQ is represented by the following equation. REQ RBOTTOM u RTOP RBOTTOM RTOP It is beneficial to use the smallest value of CC that provides stability and enough voltage ripple at feedback. Larger values of CC may negatively affect the load regulation performance. The output voltage adjustable range for continuous-conduction operation is limited by the fixed 320ns (typical) minimum off-time. When working with low input voltages, the duty-factor limit must be calculated using worstcase values for on and off times. The duty-factor limitation is shown by the next equation. DUTY t ON(MIN) t ON(MIN) t OFF(MAX ) The inductor resistance and MOSFET on-state voltage drops must be included when performing worst-case dropout duty-factor calculations. System DC Accuracy — VOUT Controller Three factors affect VOUT accuracy: the trip point of the FB error comparator, the ripple voltage variation with line and load, and the external resistor tolerance. The error comparator offset is trimmed so that under static conditions it trips when the feedback pin is 750mV, +1%. The on-time pulse from the SC410 in the design example is calculated to give a pseudo-fixed frequency of 500kHz. Some frequency variation with line and load is expected. This variation changes the output ripple voltage. Because adaptive on-time converters regulate to the valley of the output ripple, ½ of the output ripple appears as a DC regulation error. To compensate for valley regulation, it may be desirable to use passive droop. Take the feedback directly from the output side of the inductor and place a small amount of trace resistance between the inductor and output capacitor. This trace resistance should be optimized so that at full load the output droops to near the lower regulation limit. Passive droop minimizes the required output capacitance because the voltage excursions due to load steps are reduced as seen at the load. The use of 1% feedback resistors may result in up to an additional 1% error. If tighter DC accuracy is required, resistors with lower tolerances should be used. 20 SC410 Applications Information (continued) The output inductor value may change with current. This will change the output ripple and therefore will have a minor effect on the DC output voltage. The output ESR also affects the output ripple and thus has a minor effect on the DC output voltage. Switching Frequency Variation The switching frequency will vary depending on line and load conditions. The line variations are a result of fixed propagation delays in the on-time one-shot, as well as unavoidable delays in the power FET switching. As VIN increases, these factors make the actual DH on-time slightly longer than the ideal on-time. The net effect is that frequency tends to fall slightly with increasing input voltage. The switching frequency also varies with load current as a result of the power losses in the MOSFETs and the inductor. For a conventional PWM constant-frequency converter, as load increases the duty cycle also increases slightly to compensate for IR and switching losses in the MOSFETs and inductor. An adaptive on-time converter must also compensate for the same losses by increasing the effective duty cycle (more time is spent drawing energy from VIN as losses increase). The on-time is essentially constant for a given VOUT and VIN combination, to offset the losses the off-time will tend to reduce slightly as load increases. The net effect is that switching frequency increases slightly with increasing load. 21 SC410 Applications Information (continued) PCB Layout Guidelines The optimum layout for the SC410 is shown in Figure 11. This layout shows an integrated FET buck regulator with a maximum current of 3A. The total PCB area is approximately 19.1mm x 11.3mm. Critical Layout Guidelines The following critical layout guidelines must be followed to ensure proper performance of the device. • • • • • • IC Decoupling capacitors PGND plane AGND island FB and other analog control signals BST and LX Capacitors and Current Loops PGND Plane PGND requires its own copper plane with no other signal traces routed on it. Copper planes, multiple vias, and wide traces are needed to connect PGND to input capacitors, output capacitors, and the PGND pins on the IC. The PGND copper area between the input capacitors, output capacitors, and PGND pins must be as small as and as compact as possible to reduce the area of the PCB that is exposed to noise due to current flow on this node. Connect PGND to AGND with a short trace or 0Ω resistor. This connection should be as close to the IC as possible. • • • • IC Decoupling Capacitors A 0.1 μF capacitor must be located as close as possible to the IC and directly connected to pins 10 (LDO) and 9 (AGND). All other decoupling capacitors must be located as close as possible to the IC. • • LX connection using a Via AGND Island AGND should have its own island of copper with no other signal traces routed on this layer that connects the AGND pins and pad of the IC to the analog control components. All of the components for the analog control circuitry should be located so that the connections • • SC410 FB node VESR node PGND Figure 11 — PCB Layout 22 SC410 Applications Information (continued) • to AGND are done by wide copper traces or vias down to AGND. Connect PGND to AGND with a short trace or 0Ω resistor. This connection should be as close to the IC as possible. FB and Other Analog Control Signals The connection from the V OUT power to the analog control circuitry must be routed from the output capacitors and located on a quiet layer. The traces between VOUT and the analog control circuitry (AGND, and FB pins) must be as short as possible. The traces must also be routed away from noise sources, such as BST, LX, VIN, and PGND between the input capacitors, output capacitors, and the IC. The TON node must be as short as possible to ensure the best accuracy for the on time. The feedback components for the switcher need to be as close to the FB pin of the IC as possible to reduce the possibility of noise corrupting these analog signals. • • • • BST and LX LX and BST are very noisy nodes and must be carefully routed to minimized the PCB area that is exposed to these signals. The connections for the boost capacitor between the IC and LX must be short and directly connected to the LX (pin 3). The LX node between the IC and the inductor should be wide enough to handle the inductor current and short enough to eliminate the possibility of LX noise corrupting other signals. • • • Capacitors and Current Loops The current loops between the input capacitors, the IC, the inductor, and the output capacitors must be as close as possible to each other to reduce IR drop across copper planes and traces. All bypass and output capacitors must be connected as close as possible to their respective pin on the IC. • • 23 SC410 Outline Drawing — MLPD-10 3x3 D A B DIM A A1 A2 b D D1 E E1 e L N aaa bbb E PIN 1 INDICATOR (LASER MARK) A aaa C 1 .031 .039 .000 .002 (.008) .008 .010 .012 .114 .118 .122 .087 .089 .091 .114 .118 .122 .057 .059 .061 .020 BSC .018 .020 .022 10 .003 .004 0.80 1.00 0.00 0.05 (0.20) 0.20 0.25 0.30 2.90 3.00 3.10 2.20 2.25 2.30 2.90 3.00 3.10 1.45 1.50 1.55 0.50 BSC 0.45 0.50 0.55 10 0.08 0.10 SEATING PLANE C A1 D1 DIMENSIONS INCHES MILLIMETERS MIN NOM MAX MIN NOM MAX A2 2 LxN E/2 E1 N e D/2 bxN bbb C A B NOTES: 1. CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES). 2. COPLANARITY APPLIES TO THE EXPOSED PAD AS WELL AS TERMINALS. 24 SC410 Land Pattern — MLPD-10 3x3 K DIM G (C) H Y X P Z DIMENSIONS INCHES MILLIMETERS C G H K P X Y Z (.112) .079 .059 .089 .020 .012 .033 .146 (2.85) 2.00 1.50 2.25 0.50 0.30 0.85 3.70 NOTES: 1. CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES). 2. THIS LAND PATTERN IS FOR REFERENCE PURPOSES ONLY. CONSULT YOUR MANUFACTURING GROUP TO ENSURE YOUR COMPANY'S MANUFACTURING GUIDELINES ARE MET. 3. THERMAL VIAS IN THE LAND PATTERN OF THE EXPOSED PAD SHALL BE CONNECTED TO A SYSTEM GROUND PLANE. FAILURE TO DO SO MAY COMPROMISE THE THERMAL AND/OR FUNCTIONAL PERFORMANCE OF THE DEVICE. 25 SC410 © Semtech 2011 All rights reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent or other industrial or intellectual property rights. Semtech assumes no responsibility or liability whatsoever for any failure or unexpected operation resulting from misuse, neglect improper installation, repair or improper handling or unusual physical or electrical stress including, but not limited to, exposure to parameters beyond the specified maximum ratings or operation outside the specified range. SEMTECH PRODUCTS ARE NOT DESIGNED, INTENDED, AUTHORIZED OR WARRANTED TO BE SUITABLE FOR USE IN LIFESUPPORT APPLICATIONS, DEVICES OR SYSTEMS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF SEMTECH PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE UNDERTAKEN SOLELY AT THE CUSTOMER’S OWN RISK. Should a customer purchase or use Semtech products for any such unauthorized application, the customer shall indemnify and hold Semtech and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs damages and attorney fees which could arise. 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