LT3435 High Voltage 3A, 500kHz Step-Down Switching Regulator with 100µA Quiescent Current DESCRIPTIO U FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ The LT®3435 is a 500kHz monolithic buck switching regulator that accepts input voltages up to 60V. A high efficiency 3A, 0.1Ω switch is included on the die along with all the necessary oscillator, control and logic circuitry. Current mode topology is used for fast transient response and good loop stability. Wide Input Range: 3.3V to 60V 3A Peak Switch Current Burst Mode® Operation: 100µA Quiescent Current** Low Shutdown Current: IQ < 1µA Power Good Flag with Programmable Threshold Load Dump Protection to 60V 500kHz Switching Frequency Saturating Switch Design: 0.1Ω On-Resistance Peak Switch Current Maintained Over Full Duty Cycle Range* 1.25V Feedback Reference Voltage Easily Synchronizable Soft-Start Capability Small 16-Pin Thermally Enhanced TSSOP Package Innovative design techniques along with a new high voltage process achieve high efficiency over a wide input range. Efficiency is maintained over a wide output current range by employing Burst Mode operation at low currents, utilizing the output to bias the internal circuitry, and by using a supply boost capacitor to fully saturate the power switch. Patented circuitry maintains peak switch current over the full duty cycle range.* Shutdown reduces input supply current to less than 1µA. External synchronization can be implemented by driving the SYNC pin with logic-level inputs. A single capacitor from the CSS pin to the output provides a controlled output voltage ramp (soft-start). The device also has a power good flag with a programmable threshold and time-out and thermal shutdown protection. U APPLICATIO S ■ ■ ■ ■ ■ ■ High Voltage Power Conversion 14V and 42V Automotive Systems Industrial Power Systems Distributed Power Systems Battery-Powered Systems USB Powered Systems The LT3435 is available in a 16-pin TSSOP package with an exposed pad leadframe for low thermal resistance. , LTC and LT are registered trademarks of Linear Technology Corporation. Burst Mode is a registered trademark of Linear Technology Corporation. All other trademarks are the property of their respective owners. *Protected by U.S. Patents including 6498466 **See Burst Mode Operation section for conditions. U TYPICAL APPLICATIO BOOST SHDN 470pF 0.1µF CT SYNC GND 4148 B360A CSS VBIAS 10k 1µF SW LT3435 VC 4700pF 0.33µF 15µH FB PGFB PG 27pF 165k 1% 100k 1% + 100µF 10V TANT 10 VIN = 12V 90 125 80 100 EFFICIENCY (%) VIN 100 VOUT = 3.3V TA = 25°C 75 50 70 VOUT = 5V 1 EFFICIENCY 60 50 VOUT = 3.3V 40 0.1 TYPICAL POWER LOSS 30 0.01 20 25 POWER LOSS (W) 4.7µF 100V CER 150 VOUT 3.3V 2A SUPPLY CURRENT (µA) VIN Efficiency and Power Loss vs Load Current Supply Current vs Input Voltage 14V to 3.3V Step-Down Converter with 100µA No Load Quiescent Current 10 0 3435 TA01 0 10 30 40 20 INPUT VOLTAGE (V) 50 60 0 0.0001 0.001 0.1 0.01 LOAD CURRENT (A) 1 0.001 10 3435 TA02 3435 TA03 3435fa 1 LT3435 U W W W ABSOLUTE AXI U RATI GS U W U PACKAGE/ORDER I FOR ATIO (Note 1) VIN, SHDN, BIAS, PGOOD, SW ............................... 60V BOOST Pin Above SW ............................................ 35V BOOST Pin Voltage ................................................. 68V SYNC, CSS, PGFB, FB ................................................ 6V Operating JunctionTemperature Range (Note 2) ........................................... – 40°C to 125°C Storage Temperature Range ................. – 65°C to 150°C Lead Temperature (Soldering, 10 sec).................. 300°C TOP VIEW NC 1 16 PGOOD SW 2 15 SHDN 14 SYNC VIN 3 VIN 4 SW 5 12 FB BOOST 6 11 VC CT 7 10 BIAS GND 8 9 17 13 PGFB CSS FE PACKAGE 16-LEAD PLASTIC TSSOP TJMAX = 125°C, θJA = 45°C/W, θJC(PAD) = 10°C/W EXPOSED PAD (PIN 17) IS GND, MUST BE SOLDERED TO GND (PIN 8) ORDER PART NUMBER FE PART MARKING LT3435EFE LT3435IFE 3435EFE 3435IFE Order Options Tape and Reel: Add #TR Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF Lead Free Part Marking: http://www.linear.com/leadfree/ Consult LTC Marketing for parts specified with wider operating temperature ranges. ELECTRICAL CHARACTERISTICS The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TJ = 25°C. VIN = 12V, SHDN = 12V, BIAS = 5V, FB/PGFB = 1.25V, CSS/SYNC = 0V unless otherwise noted. SYMBOL PARAMETER VSHDN SHDN Threshold ISHDN SHDN Input Current CONDITIONS SHDN = 12V Minimum Input Voltage (Note 3) IVINS IVIN Supply Shutdown Current SHDN = 0V, BOOST = 0V, FB/PGFB = 0V Supply Sleep Current (Note 4) BIAS = 0V, FB = 1.35V FB = 1.35V Supply Quiescent Current BIAS = 0V, FB = 1.15V BIAS = 5V, FB = 1.15V MIN TYP MAX UNITS 1.15 1.3 1.45 V ● 5 20 µA ● 2.4 3 V 0.1 2 µA 170 45 250 75 µA µA 3.3 2.6 7 6 mA mA ● ● Minimum BIAS Voltage (Note 5) ● 2.7 3.1 V IBIASS BIAS Sleep Current (Note 4) ● 125 180 µA IBIAS BIAS Quiescent Current SYNC = 3.3V 700 900 µA Minimum Boost Voltage (Note 6) ISW = 1.5A 1.8 Input Boost Current (Note 7) ISW = 3A 65 85 mA VREF Reference Voltage (VREF) 3.3V < VVIN < 60V 1.25 1.275 IFB FB Input Bias Current 75 200 EA Voltage Gain (Note 8) 900 EA Voltage gm dI(VC)= ±10µA ● 1.225 400 650 V V nA V/V 900 µMho 3435fa 2 LT3435 ELECTRICAL CHARACTERISTICS The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TJ = 25°C. VIN = 12V, SHDN = 12V, BIAS = 5V, FB/PGFB = 1.25V, CSS/SYNC = 0V unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX EA Source Current FB = 1.15V 20 40 55 µA EA Sink Current FB = 1.35V 15 30 40 µA FB = 1.15V 2.1 2.2 2.4 V 3 5.2 6.5 A 0.1 0.25 Ω 425 500 575 kHz 86 92 VC to SW gm VC High Clamp IPK 6 SW Current Limit ● Switch On Resistance (Note 9) ● Switching Frequency ● Maximum Duty Cycle Minimum SYNC Amplitude 1.5 SYNC Frequency Range 575 SYNC Input Impedance A/V % 2.0 V 700 kHz 45 kΩ 13 20 µA 25 100 nA 88 90 92 % CT Source Current (Note 11) 2 3.6 5.5 CT Sink Current (Note 11) 1 2 1.16 1.2 1.26 V 0.1 1 µA ICSS CSS Current Threshold (Note 10) IPGFB PGFB Input Current VPGFB PGFB Voltage Threshold (Note 11) ICT VCT UNITS FB = 0V 7 ● CT Voltage Threshold (Note 11) PG Leakage (Note 11) PG Sink Current (Note 11) PGFB = 1V, PG = 400mV Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Note 2: The LT3435EFE is guaranteed to meet performance specifications from 0°C to 125°C junction temperature. Specifications over the –40°C to 125°C operating junction temperature range are assured by design, characterization and correlation with statistical process controls. The LT3435IFE is guaranteed and tested over the full –40°C to 125°C operating junction temperature range. Note 3: Minimum input voltage is defined as the voltage where switching starts. Actual minimum input voltage to maintain a regulated output will depend upon output voltage and load current. See Applications Information. Note 4: Supply input current is the quiescent current drawn by the input pin. Its typical value depends on the voltage on the BIAS pin and operating state of the LT3435. With the BIAS pin at 0V, all of the quiescent current required to operate the LT3435 will be provided by the VIN pin. With the BIAS voltage above its minimum input voltage, a portion of the total quiescent current will be supplied by the BIAS pin. Supply sleep current is defined as the quiescent current during the “sleep” portion of Burst Mode operation. See Applications Information for determining application supply currents. 100 200 µA mA µA Note 5: Minimum BIAS voltage is the voltage on the BIAS pin when IBIAS is sourced into the pin. Note 6: This is the minimum voltage across the boost capacitor needed to guarantee full saturation of the internal power switch. Note 7: Boost current is the current flowing into the BOOST pin with the pin held 3.3V above input voltage. It flows only during switch on time. Note 8: Gain is measured with a VC swing from 1.15V to 750mV. Note 9: Switch on resistance is calculated by dividing VIN to SW voltage by the forced current (3A). See Typical Performance Characteristics for the graph of switch voltage at other currents. Note 10: The CSS threshold is defined as the value of current sourced into the CSS pin which results in an increase in sink current from the VC pin. See the Soft-Start section in Applications Information. Note 11: The PGFB threshold is defined as the percentage of VREF voltage which causes the current source output of the CT pin to change from sinking (below threshold) to sourcing current (above threshold). When sourcing current, the voltage on the CT pin rises until it is clamped internally. When the clamp is activated, the output of the PG pin will be set to a high impedance state. When the CT clamp is inactive the PG pin will be set active low with a current sink capability of 200µA. 3435fa 3 LT3435 U W TYPICAL PERFOR A CE CHARACTERISTICS Oscillator Frequency 1.29 540 1.28 530 1.27 520 1.26 1.25 1.24 1.23 490 460 100 50 25 0 75 TEMPERATURE (°C) 100 1.00 –50 –25 125 Shutdown Supply Current 200 180 20 4.5 3.0 2.5 140 CURRENT (µA) CURRENT (µA) CURRENT (µA) 4.0 3.5 VBIAS = 0V 160 VIN = 60V 15 10 2.0 120 100 80 VBIAS = 5V 60 1.5 5 40 VIN = 42V 1.0 0 10 30 40 20 SHDN VOLTAGE (V) 50 0 –50 –25 60 VIN = 12V 50 25 0 75 TEMPERATURE (°C) 100 0 –50 –25 125 1.18 160 1.16 140 1.14 100 80 1.08 40 1.04 20 1.02 100 125 3435 G07 200 1.10 1.06 1.00 –50 –25 125 PG Sink Current 1.12 60 100 250 CURRENT (µA) 180 VOLTAGE (V) 1.20 120 50 25 0 75 TEMPERATURE (°C) 3435 G06 PGFB Threshold Bias Sleep Current 200 50 25 0 75 TEMPERATURE (°C) 20 3435 G05 3435 G04 0 –50 –25 125 Sleep Mode Supply Current 25 TJ = 25°C 100 3435 G03 5.0 0 50 25 0 75 TEMPERATURE (°C) 3435 G02 SHDN Pin Current CURRENT (µA) 0.15 1.05 3435 G01 5.5 1.20 1.10 450 –50 –25 125 1.25 480 1.21 50 25 0 75 TEMPERATURE (°C) 1.30 500 470 –25 1.35 510 1.22 1.20 –50 SHDN Threshold 1.40 VOLTAGE (V) 550 FREQUENCY (kHz) VOLTAGE (V) FB Voltage 1.30 150 100 50 50 25 0 75 TEMPERATURE (°C) 100 125 3435 G08 0 –50 –25 50 25 0 75 TEMPERATURE (°C) 100 125 3435 G09 3435fa 4 LT3435 U W TYPICAL PERFOR A CE CHARACTERISTICS Soft-Start Current Threshold vs FB Voltage 50 6.0 90 40 35 5.0 CURRENT (µA) PEAK SWITCH CURRENT (A) 100 TJ = 25°C 45 5.5 Oscillator Frequency vs FB Voltage NORMALIZED FREQUENCY (%) Switch Peak Current Limit 4.5 4.0 SOFT-START DEFEATED 30 25 20 15 10 3.5 0 –0 25 50 75 TEMPERATURE (°C) 100 0.2 0.6 0.8 0.4 FB VOLTAGE (V) 1.0 Switch On Voltage (VCESAT) 200 TJ = –40°C START-UP 6.0 VOUT = 5V 5.5 RUNNING 5.0 START-UP 4.5 100 VOUT = 3.3V 4.0 50 0 1.0 2.0 1.5 LOAD CURRENT (A) 2.5 0.5 1.0 1.5 2.0 LOAD CURRENT (A) 450 850 300 250 3435 G16 650 550 100 125 3435 G17 60 700 150 500 –50 –25 20 Boost Current vs Switch Current 750 600 50 25 0 75 TEMPERATURE (°C) 10 15 INPUT VOLTAGE (V) 70 800 200 100 –50 –25 300 5 BOOST CURRENT (mA) 900 FREQUENCY (kHz) ON TIME (ns) 950 500 350 BURST MODE ENTER (DECREASING LOAD) 400 Maximum Synchronization Frequency vs Temperature 550 400 500 3.0 2.5 1000 LOAD CURRENT = 1A 600 3435 G15 Minimum On-Time for Continuous Mode Operation BURST MODE EXIT (INCREASING LOAD) 0 0 3435 G13 600 VOUT = 3.3V 900 L = 15µH COUT = 100µF 800 T = 25°C A 700 100 3.0 3.0 1.25 200 RUNNING 3.5 0.5 1.00 3435 G12 LOAD CURRENT (mA) 250 0.50 0.75 FB VOLTAGE (V) 1000 6.5 INPUT VOLTAGE (V) VOLTAGE (mV) TJ = 25°C 0.25 Burst Mode Threshold vs Input Voltage 7.0 TJ = 125°C 150 20 0 7.5 300 30 Minimum Input Voltage 450 350 40 1.2 8.0 400 50 3435 G11 3435 G10 500 60 0 0 125 70 10 5 3.0 –50 –25 80 50 40 30 20 10 50 25 0 75 TEMPERATURE (°C) 100 125 3435 G14 0 0 500 1000 1500 2000 2500 SWITCH CURRENT (mA) 3000 3435 G18 3435fa 5 LT3435 U W TYPICAL PERFOR A CE CHARACTERISTICS Dropout Operation 4.0 VOUT = 3.3V BOOST DIODE = DIODES INC DFLS160 3.5 Burst Mode Operation VOUT = 5V BOOST DIODE = DIODES INC DFLS160 VOUT 50mV/DIV AC-COUPLED 5 3.0 OUTPUT VOLTAGE (V) OUTPUT VOLTAGE (V) Dropout Operation 6 2.5 2.0 1.5 LOAD CURRENT = 2.5A 1.0 LOAD CURRENT = 250mA 4 3 LOAD CURRENT = 2.5A 2 VIN = 12V VOUT = 3.3V LOAD CURRENT = 250mA 1 0.5 ISW 500mA/DIV 10ms/DIV 3435 G21 0 0 2 2.5 3 3.5 4 4.5 5 INPUT VOLTAGE (V) 5.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 INPUT VOLTAGE (V) 6 3435 G20 3435 G19 No Load 2A Step Response Burst Mode Operation VOUT 50mV/DIV AC-COUPLED Step Response VOUT 200mV/DIV AC-COUPLED VOUT 200mV/DIV AC-COUPLED IOUT 1A/DIV IOUT 1A/DIV ISW 500mA/DIV 10µs/DIV 3435 G22 VIN = 12V VOUT = 3.3V COUT = 100µF 500µs/DIV 3435 G23 500µs/DIV VIN = 12V VOUT = 3.3V COUT = 100µF ILOAD(DC) = 500mA 3435 G24 U VIN = 12V VOUT = 3.3V U U PI FU CTIO S NC (Pin 1): No Connection. SW (Pins 2, 5): The SW pin is the emitter of the on-chip power NPN switch. This pin is driven up to the input pin voltage during switch on time. Inductor current drives the SW pin negative during switch off time. Negative voltage is clamped with the external catch diode. Maximum negative switch voltage allowed is –0.8V. VIN (Pins 3, 4): This is the collector of the on-chip power NPN switch. VIN powers the internal control circuitry when a voltage on the BIAS pin is not present. High di/dt edges occur on this pin during switch turn on and off. Keep the path short from the VIN pin through the input bypass capacitor, through the catch diode back to SW. All trace inductance on this path will create a voltage spike at switch off, adding to the VCE voltage across the internal NPN. BOOST (Pin 6): The BOOST pin is used to provide a drive voltage, higher than the input voltage, to the internal bipolar NPN power switch. Without this added voltage, the typical switch voltage loss would be about 1.5V. The additional BOOST voltage allows the switch to saturate and its voltage loss approximates that of a 0.1Ω FET structure. CT (Pin 7): A capacitor on the CT pin determines the amount of delay time between the PGFB pin exceeding its threshold (VPGFB) and the PG pin set to a high impedance state. 3435fa 6 LT3435 U U U PI FU CTIO S When the PGFB pin rises above VPGFB, current is sourced from the CT pin into the external capacitor. When the voltage on the external capacitor reaches an internal clamp (VCT), the PG pin becomes a high impedance node. The resultant PG delay time is given by t = CCT • VCT/ICT. If the voltage on the PGFB pin drops below VPGFB, CCT will be discharged rapidly to 0V and PG will be active low with a 200µA sink capability. If the CT pin is clamped (Power Good condition) during normal operation and SHDN is taken low, the CT pin will be discharged and a delay period will occur when SHDN is returned high. See the Power Good section in Applications Information for details. GND (Pins 8, 17): The GND pin connection acts as the reference for the regulated output, so load regulation will suffer if the “ground” end of the load is not at the same voltage as the GND pin of the IC. This condition will occur when load current or other currents flow through metal paths between the GND pin and the load ground. Keep the path between the GND pin and the load ground short and use a ground plane when possible. The GND pin also acts as a heat sink and should be soldered (along with the exposed leadframe) to the copper ground plane to reduce thermal resistance (see Applications Information). CSS (Pin 9): A capacitor from the CSS pin to the regulated output voltage determines the output voltage ramp rate during start-up. When the current through the CSS capacitor exceeds the CSS threshold (ICSS), the voltage ramp of the output is limited. The CSS threshold is proportional to the FB voltage (see Typical Performance Characteristics) and is defeated for FB voltage greater than 0.9V (typical). See Soft-Start section in Applications Information for details. BIAS (Pin 10): The BIAS pin is used to improve efficiency when operating at higher input voltages and light load current. Connecting this pin to the regulated output voltage forces most of the internal circuitry to draw its operating current from the output voltage rather than the input supply. This architecture increases efficiency especially when the input voltage is much higher than the output. Minimum output voltage setting for this mode of operation is 3V. VC (Pin 11): The VC pin is the output of the error amplifier and the input of the peak switch current comparator. It is normally used for frequency compensation, but can also serve as a current clamp or control loop override. VC sits at about 0.45V for light loads and 2.2V at maximum load. During the sleep portion of Burst Mode operation, the VC pin is held at a voltage slightly below the burst threshold for better transient response. Driving the VC pin to ground will disable switching and place the IC into sleep mode. FB (Pin 12): The feedback pin is used to determine the output voltage using an external voltage divider from the output that generates 1.25V at the FB pin . When the FB pin drops below 0.9V, switching frequency is reduced, the SYNC function is disabled and output ramp rate control is enabled via the CSS pin. See the Feedback section in Applications Information for details. PGFB (PIN 13): The PGFB pin is the positive input to a comparator whose negative input is set at VPGFB. When PGFB is taken above VPGFB, current (ICSS) is sourced into the CT pin starting the PG delay period. When the voltage on the PGFB pin drops below VPGFB, the CT pin is rapidly discharged resetting the PG delay period. The PGFB voltage is typically generated by a resistive divider from the regulated output or input supply. See Power Good section in Applications Information for details. SYNC (Pin 14): The SYNC pin is used to synchronize the internal oscillator to an external signal. It is directly logic compatible and can be driven with any signal between 5% and 75% duty cycle. The synchronizing range is equal to maximum initial operating frequency up to 700kHz. When the voltage on the FB pin is below 0.9V the SYNC function is disabled. See the Synchronizing section in Applications Information for details. SHDN (Pin 15): The SHDN pin is used to turn off the regulator and to reduce input current to less than 1µA. The SHDN pin requires a voltage above 1.3V with a typical source current of 5µA to take the IC out of the shutdown state. PG (Pin 16): The PG pin is functional only when the SHDN pin is above its threshold, and is active low when the internal clamp on the CT pin is below its clamp level and high impedance when the clamp is active. The PG pin has a typical sink capability of 200µA. See the Power Good section in Applications Information for details. 3435fa 7 LT3435 W BLOCK DIAGRA 4 VIN INTERNAL REF UNDERVOLTAGE LOCKOUT 10 14 15 BIAS THERMAL SHUTDOWN 2.4V SLOPE COMP Σ 500kHz OSCILLATOR + CURRENT COMP – SYNC SHDN BOOST ANTISLOPE COMP + R SHDN COMP S – SWITCH Q LATCH DRIVER CIRCUITRY SW 1.3V 9 12 CSS FB SOFT-START BURST MODE DETECT FOLDBACK DETECT VC CLAMP 6 2 – ERROR AMP 1.25V 11 13 + VC PG PGFB 16 + PG COMP 1.12V 1.2V CT CLAMP – GND 17 7 PGND 8 CT 3435 BD Figure 1. LT3435 Block Diagram The LT3435 is a constant frequency, current mode buck converter. This means that there is an internal clock and two feedback loops that control the duty cycle of the power switch. In addition to the normal error amplifier, there is a current sense amplifier that monitors switch current on a cycle-by-cycle basis. A switch cycle starts with an oscillator pulse which sets the RS latch to turn the switch on. When switch current reaches a level set by the current comparator the latch is reset and the switch turns off. Output voltage control is obtained by using the output of the error amplifier to set the switch current trip point. This technique means that the error amplifier commands current to be delivered to the output rather than voltage. A voltage fed system will have low phase shift up to the resonant frequency of the inductor and output capacitor, then an abrupt 180° shift will occur. The current fed system will have 90° phase shift at a much lower frequency, but will not have the additional 90° shift until well beyond the LC resonant frequency. This makes it much easier to frequency compensate the feedback loop and also gives much quicker transient response. Most of the circuitry of the LT3435 operates from an internal 2.4V bias line. The bias regulator normally draws 3435fa 8 LT3435 W BLOCK DIAGRA power from the VIN pin, but if the BIAS pin is connected to an external voltage higher than 3V bias power will be drawn from the external source (typically the regulated output voltage). This improves efficiency. High switch efficiency is attained by using the BOOST pin to provide a voltage to the switch driver which is higher than the input voltage, allowing switch to be saturated. This boosted voltage is generated with an external capacitor and diode. To further optimize efficiency, the LT3435 automatically switches to Burst Mode operation in light load situations. In Burst Mode operation, all circuitry associated with controlling the output switch is shut down reducing the input supply current to 45µA. The LT3435 contains a power good flag with a programmable threshold and delay time. A logic-level low on the SHDN pin disables the IC and reduces input suppy current to less than 1µA. U W U U APPLICATIO S I FOR ATIO FEEDBACK PIN FUNCTIONS Table 1 The feedback (FB) pin on the LT3435 is used to set output voltage and provide several overload protection features. The first part of this section deals with selecting resistors to set output voltage and the remaining part talks about frequency foldback and soft-start features. Please read both parts before committing to a final design. OUTPUT VOLTAGE (V) R2 (kΩ, 1%) R1 NEAREST (1%) (kΩ) OUTPUT ERROR (%) 2.5 100 100 0 Referring to Figure 2, the output voltage is determined by a voltage divider from VOUT to ground which generates 1.25V at the FB pin. Since the output divider is a load on the output care must be taken when choosing the resistor divider values. For light load applications the resistor values should be as large as possible to achieve peak efficiency in Burst Mode operation. Extremely large values for resistor R1 will cause an output voltage error due to the 50nA FB pin input current. The suggested value for the output divider resistor (see Figure 2) from FB to ground (R2) is 100k or less. A formula for R1 is shown below. A table of standard 1% values is shown in Table 1 for common output voltages. R1 = R2 • VOUT – 1.25 1.25 + R2 • 50nA 3 100 140 0 3.3 100 165 0.38 5 100 301 0.25 6 100 383 0.63 8 100 536 – 0.63 10 100 698 – 0.25 12 100 866 0.63 VOUT LT3435 SW 2 SOFT-START 500kHz OSCILLATOR CSS C1 9 FOLDBACK DETECT R1 – FB 12 ERROR AMP R2 + More Than Just Voltage Feedback The FB pin is used for more than just output voltage sensing. It also reduces switching frequency and controls the soft-start voltage ramp rate when output voltage is below the regulated level (see the Frequency Foldback 1.25V VC 11 3435 F02 Figure 2. Feedback Network 3435fa 9 LT3435 U W U U APPLICATIO S I FOR ATIO and Soft-Start Current graphs in Typical Performance Characteristics). Frequency foldback is done to control power dissipation in both the IC and in the external diode and inductor during short-circuit conditions. A shorted output requires the switching regulator to operate at very low duty cycles. As a result the average current through the diode and inductor is equal to the short-circuit current limit of the switch (typically 4.7A for the LT3435). Minimum switch on time limitations would prevent the switcher from attaining a sufficiently low duty cycle if switching frequency were maintained at 500kHz, so frequency is reduced by about 4:1 when the FB pin voltage drops below 0.4V (see Frequency Foldback graph). In addition, if the current in the switch exceeds 1.5 times the current limitations specified by the VC pin, due to minimum switch on time, the LT3435 will skip the next switch cycle. As the feedback voltage rises, the switching frequency increases to 500kHz with 0.95V on the FB pin. During frequency foldback, external syncronization is disabled to prevent interference with foldback operation. Frequency foldback does not affect operation during normal load conditions. In addition to lowering switching frequency the soft-start ramp rate is also affected by the feedback voltage. Large capacitive loads or high input voltages can cause a high input current surge during start-up. The soft-start function reduces input current surge by regulating switch current via the VC pin to maintain a constant voltage ramp rate (dV/dt) at the output. A capacitor (C1 in Figure 2) from the CSS pin to the output determines the maximum output dV/dt. When the feedback voltage is below 0.4V, the VC pin will rise, resulting in an increase in switch current and output voltage. If the dV/dt of the output causes the current through the CSS capacitor to exceed ICSS the VC voltage is reduced resulting in a constant dV/dt at the output. As the feedback voltage increases ICSS increases, resulting in an increased dV/dt until the soft-start function is defeated with 0.9V present at the FB pin. The soft-start function does not affect operation during normal load conditions. However, if a momentary short (brown out condition) is present at the output which causes the FB voltage to drop below 0.9V, the soft-start circuitry will become active. INPUT CAPACITOR Step-down regulators draw current from the input supply in pulses. The rise and fall times of these pulses are very fast. The input capacitor is required to reduce the voltage ripple this causes at the input of LT3435 and force the switching current into a tight local loop, thereby minimizing EMI. The RMS ripple current can be calculated from: IRIPPLE(RMS) = ( IOUT VOUT VIN – VOUT VIN ) Ceramic capacitors are ideal for input bypassing. At 500kHz switching frequency input capacitor values in the range of 4.7µF to 20µF are suitable for most applications. If operation is required close to the minimum input required by the LT3435 a larger value may be required. This is to prevent excessive ripple causing dips below the minimum operating voltage resulting in erratic operation. Input voltage transients caused by input voltage steps or by hot plugging the LT3435 to a pre-powered source such as a wall adapter can exceed maximum VIN ratings. The sudden application of input voltage will cause a large surge of current in the input leads that will store energy in the parasitic inductance of the leads. This energy will cause the input voltage to swing above the DC level of input power source and it may exceed the maximum voltage rating of the input capacitor and LT3435. All input voltage transient sequences should be observed at the VIN pin of the LT3435 to ensure that absolute maximum voltage ratings are not violated. The easiest way to suppress input voltage transients is to add a small aluminum electrolytic capacitor in parallel with the low ESR input capacitor. The selected capacitor needs to have the right amount of ESR to critically damp the resonant circuit formed by the input lead inductance and the input capacitor. The typical values of ESR will fall in the range of 0.5Ω to 2Ω and capacitance will fall in the range of 5µF to 50µF. If tantalum capacitors are used, values in the 22µF to 470µF range are generally needed to minimize ESR and meet ripple current and surge ratings. Care should be 3435fa 10 LT3435 U W U U APPLICATIO S I FOR ATIO taken to ensure the ripple and surge ratings are not exceeded. The AVX TPS and Kemet T495 series are surge rated AVX recommends derating capacitor operating voltage by 2:1 for high surge applications. OUTPUT CAPACITOR Output capacitor ripple current (RMS) The output capacitor is normally chosen by its effective series resistance (ESR) because this is what determines output ripple voltage. To get low ESR takes volume, so physically smaller capacitors have higher ESR. The ESR range for typical LT3435 applications is 0.05Ω to 0.2Ω. A typical output capacitor is an AVX type TPS, 100µF at 10V, with a guaranteed ESR less than 0.1Ω. This is a “D” size surface mount solid tantalum capacitor. TPS capacitors are specially constructed and tested for low ESR, so they give the lowest ESR for a given volume. The value in microfarads is not particularly critical and values from 22µF to greater than 500µF work well, but you cannot cheat Mother Nature on ESR. If you find a tiny 22µF solid tantalum capacitor, it will have high ESR and output ripple voltage could be unacceptable. Table 2 shows some typical solid tantalum surface mount capacitors. Table 2. Surface Mount Solid Tantalum Capacitor ESR and Ripple Current E CASE SIZE AVX TPS ESR MAX (Ω) RIPPLE CURRENT (A) 0.1 to 0.3 0.7 to 1.1 0.1 to 0.3 0.7 to 1.1 0.2 0.5 D CASE SIZE AVX TPS Unlike the input capacitor RMS, ripple current in the output capacitor is normally low enough that ripple current rating is not an issue. The current waveform is triangular with a typical value of 200mARMS. The formula to calculate this is: IRIPPLE(RMS) = ( )( (L)(f)(VIN) 0.29 VOUT VIN – VOUT ) = IP-P 12 CERAMIC CAPACITORS Higher value, lower cost ceramic capacitors are now becoming available. They are generally chosen for their good high frequency operation, small size and very low ESR (effective series resistance). Low ESR reduces output ripple voltage but also removes a useful zero in the loop frequency response, common to tantalum capacitors. To compensate for this a resistor RC can be placed in series with the VC compensation capacitor CC (Figure 10). Care must be taken however since this resistor sets the high frequency gain of the error amplifier including the gain at the switching frequency. If the gain of the error amplifier is high enough at the switching frequency output ripple voltage (although smaller for a ceramic output capacitor) may still affect the proper operation of the regulator. A filter capacitor CF in parallel with the RC/CC network, along with a small feedforward capacitor CFB, is suggested to control possible ripple at the VC pin. C CASE SIZE AVX TPS Many engineers have heard that solid tantalum capacitors are prone to failure if they undergo high surge currents. This is historically true and type TPS capacitors are specially tested for surge capability but surge ruggedness is not a critical issue with the output capacitor. Solid tantalum capacitors fail during very high turn-on surges which do not occur at the output of regulators. High discharge surges, such as when the regulator output is dead shorted, do not harm the capacitors. OUTPUT RIPPLE VOLTAGE Figure 3 shows a typical output ripple voltage waveform for the LT3435. Ripple voltage is determined by the impedance of the output capacitor and ripple current through the inductor. Peak-to-peak ripple current through the inductor into the output capacitor is: IP-P = ( VOUT VIN – VOUT (VIN )(L)(f) ) 3435fa 11 LT3435 U W U U APPLICATIO S I FOR ATIO does not fall off at high duty cycles. Most current mode converters suffer a drop off of peak switch current for duty cycles above 50%. This is due to the effects of slope compensation required to prevent subharmonic oscillations in current mode converters. (For detailed analysis, see Application Note 19.) VOUT 20mV/DIV AC-COUPLED COUT = 100µF TANTALUM ESR 100mΩ VOUT 20mV/DIV AC-COUPLED COUT = 100µF CERAMIC VSW 5V/DIV VIN = 12V VOUT = 3.3V ILOAD = 1A L = 15µH 500ns/DIV 3435 F03 Figure 3. LT3435 Ripple Voltage Waveform For high frequency switchers the ripple current slew rate is also relevant and can be calculated from: di VIN = dt L Peak-to-peak output ripple voltage is the sum of a triwave created by peak-to-peak ripple current times ESR and a square wave created by parasitic inductance (ESL) and ripple current slew rate. Capacitive reactance is assumed to be small compared to ESR or ESL. ( )( ) ( ) di dt Example: with VIN = 12V, VOUT = 3.3V, L = 15µH, ESR = 0.08Ω, ESL = 10nH: VRIPPLE = IP-P ESR + ESL IP-P = (3.3)(12 – 3.3) = 0.319A (12)(15e − 6)(500e3) di 12 = = 0.8e6 dt 15e – 6 VRIPPLE = (0.319A)(0.08) + (10e – 9)(0.8e6) = 0.026 + 0.008 = 34mVP-P MAXIMUM OUTPUT LOAD CURRENT Maximum load current for a buck converter is limited by the maximum switch current rating (IPK). The current rating for the LT3435 is 3A. Unlike most current mode converters, the LT3435 maximum switch current limit The LT3435 is able to maintain peak switch current limit over the full duty cycle range by using patented circuitry to cancel the effects of slope compensation on peak switch current without affecting the frequency compensation it provides. Maximum load current would be equal to maximum switch current for an infinitely large inductor, but with finite inductor size, maximum load current is reduced by one-half peak-to-peak inductor current. The following formula assumes continuous mode operation, implying that the term on the right (IP-P/2) is less than IOUT. IOUT(MAX) = IPK – (VOUT )(VIN – VOUT ) = IPK – IP-P 2 2(L)( f)(VIN ) Discontinuous operation occurs when: IOUT(DIS) ≤ ( VOUT VIN – VOUT ) 2(L)( f)(VIN ) For VOUT = 5V, VIN = 8V and L = 15µH: IOUT(MAX) = 3 – (5)(8 – 5) 2(15e – 6)(500e3)(8) = 3 – 0.125 = 2.875A Note that there is less load current available at the higher input voltage because inductor ripple current increases. At VIN = 15V, duty cycle is 33% and for the same set of conditions: IOUT(MAX) = 3 – (5)(15 – 5) 2(15e – 6)(500e3)(15) = 3 – 0.22 = 2.88 A 3435fa 12 LT3435 U W U U APPLICATIO S I FOR ATIO To calculate actual peak switch current in continuous mode with a given set of conditions, use: ISW(PK) = IOUT + ( VOUT VIN – VOUT ( )( )( ) ) 2 L f VIN If a small inductor is chosen which results in discontinous mode operation over the entire load range, the maximum load current is equal to: ( )( )( ) IOUT(MAX) = 2(VOUT )(VIN – VOUT ) 2 IPK 2 f L VIN CHOOSING THE INDUCTOR For most applications the output inductor will fall in the range of 5µH to 33µH. Lower values are chosen to reduce physical size of the inductor. Higher values allow more output current because they reduce peak current seen by the LT3435 switch, which has a 3A limit. Higher values also reduce output ripple voltage and reduce core loss. When choosing an inductor you might have to consider maximum load current, core and copper losses, allowable component height, output voltage ripple, EMI, fault current in the inductor, saturation and of course cost. The following procedure is suggested as a way of handling these somewhat complicated and conflicting requirements. 1. Choose a value in microhenries such that the maximum load current plus half of the inductor ripple current is less than the minimum peak switch current (IPK). Choosing a small inductor with lighter loads may result in discontinuous mode of operation, but the LT3435 is designed to work well in either mode. Assume that the average inductor current is equal to load current and decide whether or not the inductor must withstand continuous fault conditions. If maximum load current is 1A, for instance, a 1A inductor may not survive a continuous 4A overload condition. Table 3. Inductor Selection Criteria VENDOR/ PART NO. VALUE (µH) IDC(MAX) (Amps) DCR (Ohms) HEIGHT (mm) Sumida CDRH104R-4R7 4.7 6 0.013 4 CDRH104R-100 10 4.4 0.035 4 CDRH104R-150 15 3.6 0.050 4 CDRH104R-220 22 2.9 0.073 4 CDRH104R-330 33 2.3 0.093 4 CDRH124-4R7 4.7 5.7 0.015 4.5 CDRH124-100 10 4.5 0.026 4.5 CDRH124-220 22 2.9 0.066 4.5 CDRH124R-330 33 2.7 0.097 4.5 CDRH127-330 33 3.0 0.065 8 CEI122-220 22 2.3 0.085 34 UP3B-4R7 4.7 6.5 0.0083 6.8 UP3B-4R7 10 4.3 0.026 6.8 UP3B-330 33 3 0.069 6.8 Coiltronics For applications with a duty cycle above 50%, the inductor value should be chosen to obtain an inductor ripple current of less than 40% of the peak switch current. 2. Calculate peak inductor current at full load current to ensure that the inductor will not saturate. Peak current can be significantly higher than output current, especially with smaller inductors and lighter loads, so don’t omit this step. Powdered iron cores are forgiving because they saturate softly, whereas ferrite cores saturate abruptly. Other core materials fall somewhere in between. The following formula assumes continuous mode of operation, but it errs only slightly on the high side for discontinuous mode, so it can be used for all conditions. IPEAK = IOUT + ( ) 2( f)(L)(VIN ) VOUT VIN – VOUT VIN = maximum input voltage f = switching frequency, 500kHz 3435fa 13 LT3435 U W U U APPLICATIO S I FOR ATIO 3. Decide if the design can tolerate an “open” core geometry like a rod or barrel, which have high magnetic field radiation, or whether it needs a closed core like a toroid to prevent EMI problems. This is a tough decision because the rods or barrels are temptingly cheap and small and there are no helpful guidelines to calculate when the magnetic field radiation will be a problem. 4. After making an initial choice, consider the secondary things like output voltage ripple, second sourcing, etc. Use the experts in the Linear Technology’s applications department if you feel uncertain about the final choice. They have experience with a wide range of inductor types and can tell you about the latest developments in low profile, surface mounting, etc. Short-Circuit Considerations The LT3435 is a current mode controller. It uses the VC node voltage as an input to a current comparator which turns off the output switch on a cycle-by-cycle basis as this peak current is reached. The internal clamp on the VC node, nominally 2.2V, then acts as an output switch peak current limit. This action becomes the switch current limit specification. The maximum available output power is then determined by the switch current limit. A potential controllability problem could occur under short-circuit conditions. If the power supply output is short circuited, the feedback amplifier responds to the low output voltage by raising the control voltage, VC, to its peak current limit value. Ideally, the output switch would be turned on, and then turned off as its current exceeded the value indicated by VC. However, there is finite response time involved in both the current comparator and turn-off of the output switch. These result in a minimum on time tON(MIN). When combined with the large ratio of VIN to (VF + I • R), the diode forward voltage plus inductor I • R voltage drop, the potential exists for a loss of control. Expressed mathematically the requirement to maintain control is: f • tON ≤ VF + I • R VIN where: f = switching frequency tON = switch on time VF = diode forward voltage VIN = Input voltage I • R = inductor I • R voltage drop If this condition is not observed, the current will not be limited at IPK but will cycle-by-cycle ratchet up to some higher value. Using the nominal LT3435 clock frequency of 500kHz, a VIN of 12V and a (VF + I • R) of say 0.7V, the maximum tON to maintain control would be approximately 116ns, an unacceptably short time. The solution to this dilemma is to slow down the oscillator to allow the current in the inductor to drop to a sufficiently low value such that the current doesn’t continue to ratchet higher. When the FB pin voltage is abnormally low thereby indicating some sort of short-circuit condition, the oscillator frequency will be reduced. Oscillator frequency is reduced by a factor of 4 when the FB pin voltage is below 0.4V and increases linearly to its typical value of 500kHz at a FB voltage of 0.95V (see Typical Performance Characteristics). In addition, if the current in the switch exceeds 1.5 • IPK current demanded by the VC pin, the LT3435 will skip the next on cycle effectively reducing the oscillator frequency by a factor of 2. These oscillator frequency reductions during short-circuit conditions allow the LT3435 to maintain current control. SOFT-START For applications where [VIN/(VOUT + VF)] ratios > 10 or large input surge currents can’t be tolerated, the LT3435 soft-start feature should be used to control the output capacitor charge rate during start-up, or during recovery from an output short circuit thereby adding additional control over peak inductor current. The soft-start function limits the switch current via the VC pin to maintain a constant voltage ramp rate (dV/dt) at the output capacitor. A capacitor (C1 in Figure 2) from the CSS pin to the regulated output voltage determines the output voltage 3435fa 14 LT3435 U W U U APPLICATIO S I FOR ATIO ramp rate. When the current through the CSS capacitor exceeds the CSS threshold (ICSS), the voltage ramp of the output capacitor is limited by reducing the VC pin voltage. The CSS threshold is proportional to the FB voltage (see Typical Performance Characteristics) and is defeated for FB voltages greater than 0.9V (typical). The output dV/dt can be approximated by: The minimum average input current depends on the VIN to VOUT ratio, VC frequency compensation, feedback divider network and Schottky diode leakage. It can be approximated by the following equation: ( ⎛ V ⎞ IBIASS + IFB + IS IIN(AVG) ≅ IVINS + ISHDN + ⎜ OUT ⎟ ⎝ VIN ⎠ η () ) where dV ICSS = dt CSS but actual values will vary due to start-up load conditions, compensation values and output capacitor selection. IBIASS = BIAS pin current in sleep mode IFB = feedback network current IS = catch diode reverse leakage at VOUT η = low current efficiency (non Burst Mode operation) CCSS = 1000pF CCSS = 0.01µF VOUT 1V/DIV Example: For VOUT = 3.3V, VIN = 12V CCSS = 0.1µF VIN = 12V VOUT = 3.3V IL = 500mA IVINS = input pin current in sleep mode VOUT = output voltage VIN = input voltage 1ms/DIV 3435 F04 ⎛ 3.3 ⎞ (125µA + 12.5µA + 0.5µA) IIN(AVG) = 45µA + 5µA + ⎜ ⎟ (0.8) ⎝ 12 ⎠ = 45µA + 5µA + 44µA = 99µA 150 Figure 4. VOUT dV/dt VOUT = 3.3V TA = 25°C To enhance efficiency at light loads, the LT3435 automatically switches to Burst Mode operation which keeps the output capacitor charged to the proper voltage while minimizing the input quiescent current. During Burst Mode operation, the LT3435 delivers short bursts of current to the output capacitor followed by sleep periods where the output power is delivered to the load by the output capacitor. In addition, VIN and BIAS quiescent currents are reduced to typically 45µA and 125µA respectively during the sleep time. As the load current decreases towards a no load condition, the percentage of time that the LT3435 operates in sleep mode increases and the average input current is greatly reduced resulting in higher efficiency. SUPPLY CURRENT (µA) 125 Burst Mode OPERATION 100 75 50 25 0 0 10 30 40 20 INPUT VOLTAGE (V) 50 60 3435 F05 Figure 5. IQ vs VIN During the sleep portion of the Burst Mode Cycle, the VC pin voltage is held just below the level need for normal operation to improve transient response. See the Typical Performance Characteristics section for burst and transient response waveforms. 3435fa 15 LT3435 U W U U APPLICATIO S I FOR ATIO If a no load condition can be anticipated, the supply current can be further reduced by cycling the SHDN pin at a rate higher than the natural no load burst frequency. Figure 6 shows Burst Mode operation with the SHDN pin. VOUT burst ripple is maintained while the average supply current drops to 15µA. The PG pin will be active low during the “on” portion of the SHDN waveform due to the CT capacitor discharge when SHDN is taken low. See the Power Good section for further information. Table 4. Catch Diode Selection Criteria LEAKAGE VOUT = 3.3V DIODE 25°C 125°C 25°C 125°C IL = 0A IL = 1A IR 10BQ100 0.0µA 59µA 0.72V 0.58V 125µA 74.7% Diodes Inc. B260SMA 0.1µA 242µA 0.48V 0.41V 215µA 81.7% Diodes Inc. B360SMB 0.2µA 440µA 0.45V 0.36V 270µA 82.4% 1µA 1.81mA 0.42V 0.34V 821µA 82.7% 1.7µA 2.64mA 0.40V 0.32V 1088µA 81.1% IR MBRS360TR VOUT 50mV/DIV AC-COUPLED VF AT 1A IQ at 125°C EFFICIENCY VIN =12V VIN =12V VOUT = 3.3 VOUT = 3.3V IR 30BQ100 lack of a significant reverse recovery time. Schottky diodes are generally available with reverse voltage ratings of 60V and even 100V and are price competitive with other types. VSHDN 2V/DIV ISW 1A/DIV VIN = 12V VOUT = 3.3V IQ = 15µA 100ms/DIV 3435 F06 Figure 6. Burst Mode with Shutdown Pin CATCH DIODE The catch diode carries load current during the SW off time. The average diode current is therefore dependent on the switch duty cycle. At high input to output voltage ratios the diode conducts most of the time. As the ratio approaches unity the diode conducts only a small fraction of the time. The most stressful condition for the diode is when the output is short circuited. Under this condition the diode must safely handle IPEAK at maximum duty cycle. To maximize high and low load current efficiency a fast switching diode with low forward drop and low reverse leakage should be used. Low reverse leakage is critical to maximize low current efficiency since its value over temperature can potentially exceed the magnitude of the LT3435 supply current. Low forward drop is critical for high current efficiency since the loss is proportional to forward drop. These requirements result in the use of a Schottky type diode. DC switching losses are minimized due to its low forward voltage drop and AC behavior is benign due to its The effect of reverse leakage and forward drop on efficiency for various Schottky diodes is shown in Table 4. As can be seen these are conflicting parameters and the user must weigh the importance of each specification in choosing the best diode for the application. The use of so-called “ultrafast” recovery diodes is generally not recommended. When operating in continuous mode, the reverse recovery time exhibited by “ultrafast” diodes will result in a slingshot type effect. The power internal switch will ramp up VIN current into the diode in an attempt to get it to recover. Then, when the diode has finally turned off, some tens of nanoseconds later, the VSW node voltage ramps up at an extremely high dV/dt, perhaps 5V to even 10V/ns! With real world lead inductances the VSW node can easily overshoot the VIN rail. This can result in poor RFI behavior and, if the overshoot is severe enough, damage the IC itself. BOOST PIN For most applications the boost components are a 0.33µF capacitor and a MMSD914 diode. The anode is typically connected to the regulated output voltage to generate a voltage approximately VOUT above VIN to drive the output stage (Figure 7a). However, the output stage discharges the boost capacitor during the on time of the switch. The output driver requires at least 2.5V of headroom throughout this period to keep the switch fully saturated. If the 3435fa 16 LT3435 U W U U APPLICATIO S I FOR ATIO output voltage is less than 3.3V it is recommended that an alternate boost supply is used. The boost diode can be connected to the input (Figure 7b) but care must be taken to prevent the boost voltage (VBOOST = VIN • 2) from exceeding the BOOST pin absolute maximum rating. The additional voltage across the switch driver also increases power loss and reduces efficiency. If available, an independent supply can be used to generate the required BOOST voltage (Figure 7c). Tying BOOST to VIN or an independent supply may reduce efficiency but it will reduce the minimum VIN required to start-up with light loads. If the generated BOOST voltage dissipates too much power at maximum load, the BOOST voltage the LT3435 sees can be reduced by placing a Zener diode in series with the BOOST diode (Figure 7a option). OPTIONAL VIN VIN BOOST VOUT LT3435 GND (7a) VIN BOOST LT3435 GND VOUT SW VBOOST – VSW = VIN VBOOST(MAX) = 2VIN VIN BOOST VDC LT3435 GND The SHDN pin on the LT3435 controls the operation of the IC. When the voltage on the SHDN pin is below the 1.2V shutdown threshold the LT3435 is placed in a “zero” supply current state. Driving the SHDN pin above the shutdown threshold enables normal operation. The SHDN pin has an internal sink current of 3µA. In addition to the shutdown feature, the LT3435 has an undervoltage lockout function. When the input voltage is below 2.4V, switching will be disabled. The undervoltage lockout threshold doesn’t have any hysteresis and is mainly used to insure that all internal voltages are at the correct level before switching is enabled. If an undervoltage lockout function with hysteresis is needed to limit input current at low VIN to VOUT ratios refer to Figure 8 and the following: ⎞ ⎛V V VUVLO = R1⎜ SHDN + SHDN + ISHDN⎟ + VSHDN R2 ⎠ ⎝ R3 (7b) VIN SHUTDOWN FUNCTION AND UNDERVOLTAGE LOCKOUT SW VBOOST – VSW = VOUT VBOOST(MAX) = VIN + VOUT VIN A 0.33µF boost capacitor is recommended for most applications. Almost any type of film or ceramic capacitor is suitable but the ESR should be <1Ω to ensure it can be fully recharged during the off time of the switch. The capacitor value is derived from worst-case conditions of 1700ns on time, TBD boost current and 0.7V discharge ripple. The boost capacitor value could be reduced under less demanding conditions but this will not improve circuit operation or efficiency. Under low input voltage and low load conditions a higher value capacitor will reduce discharge ripple and improve start-up operation. VHYST = VOUT SW DSS 3435 F07 VBOOST – VSW = VDC VBOOST(MAX) = VDC + VIN R3 R1 should be chosen to minimize quiescent current during normal operation by the following equation: (7c) Figure 7. BOOST Pin Configurations ( ) VOUT R1 R1 = VIN – 2V (1.5)(ISHDN(MAX) ) 3435fa 17 LT3435 U W U U APPLICATIO S I FOR ATIO Example: R1 = R3 = 12 – 2 ( ) 1.5 5µA ( 5 1.3MΩ 1 = 1.3MΩ ) = 6.5MΩ (Nearest 1% 6.49MΩ) 1.3 R2 = 1.3 7 – 1.3 – 1µA – 6.49MΩ 1.3MΩ = 408k (Nearest 1% 412k) See the Typical Performance Characteristics section for graphs of SHDN and VIN currents verses input voltage. LT3435 4 VIN VIN COMP ENABLE R1 VOUT 15 R2 SHDN + SHDN COMP 3µA If the synchronization signal is present during Burst Mode operation, synchronization will occur during the burst portion of the output waveform. Synchronizing the LT3435 during Burst Mode operation may alter the natural burst frequency which can lead to jitter and increased ripple in the burst waveform. POWER GOOD – R3 If the FB pin voltage is below 0.9V (power-up or output short-circuit conditions) the sync function is disabled. This allows the frequency foldback to operate to avoid and hazardous conditions for the SW pin. If no synchronization is required this pin should be connected to ground. + 2.4V inductor values will tend to eliminate this problem. See Frequency Compensation section for a discussion of an entirely different cause of subharmonic switching before assuming that the cause is insufficient slope compensation. Application Note 19 has more details on the theory of slope compensation. – 1.3V 3435 F08 Figure 8. Undervoltage Lockout SYNCHRONIZING Oscillator synchronization to an external input is achieved by connecting a TTL logic-compatible square wave with a duty cycle between 5% and 75% to the LT3435 SYNC pin. The synchronizing range is equal to initial operating frequency up to 700kHz. This means that minimum practical sync frequency is equal to the worst-case high self-oscillating frequency (575kHz), not the typical operating frequency of 300kHz. Caution should be used when synchronizing above 575kHz because at higher sync frequencies the amplitude of the internal slope compensation used to prevent subharmonic switching is reduced. This type of subharmonic switching only occurs at input voltages less than twice output voltage. Higher The LT3435 contains a power good block which consists of a comparator, delay timer and active low flag that allows the user to generate a delayed signal after the power good threshold is exceeded. Referring to Figure 2, the PGFB pin is the positive input to a comparator whose negative input is set at VPGFB. When PGFB is taken above VPGFB, current (ICSS) is sourced into the CT pin starting the delay period. When the voltage on the PGFB pin drops below VPGFB the CT pin is rapidly discharged resetting the delay period. The PGFB voltage is typically generated by a resistive divider from the regulated output or input supply. The capacitor on the CT pin determines the amount of delay time between the PGFB pin exceeding its threshold (VPGFB) and the PG pin set to a high impedance state. When the PGFB pin rises above VPGFB current is sourced (ICT) from the CT pin into the external capacitor. When the voltage on the external capacitor reaches an internal clamp (VCT), the PG pin becomes a high impedance node. The resultant PG delay time is given by t = CCT • (VCT)/(ICT). If the voltage on the PGFB pin drops below its VPGFB, CCT will be discharged rapidly and PG will be active low with a 200µA sink capability. If the SHDN pin is taken below its 3435fa 18 LT3435 U W U U APPLICATIO S I FOR ATIO threshold during normal operation, the CT pin will be discharged and PG inactive, resulting in a non Power Good cycle when SHDN is taken above its threshold. Figure 9 shows the power good operation with PGFB connected to FB and the capacitance on CT = 0.1µF. The PGOOD pin has a limited amount of drive capability and is susceptible to noise during start-up and Burst Mode operation. If erratic operation occurs during these conditions a small filter capacitor from the PGOOD pin to ground will ensure proper operation. Figure 10 shows several different configurations for the LT3435 Power Good circuitry. Figure 10 shows several different configurations for the LT3435 Power Good circuitry. LAYOUT CONSIDERATIONS VOUT 500mV/DIV As with all high frequency switchers, when considering layout, care must be taken in order to achieve optimal electrical, thermal and noise performance. For maximum efficiency switch rise and fall times are typically in the nanosecond range. To prevent noise both radiated and conducted the high speed switching current path, shown in Figure 11, must be kept as short as possible. This is implemented in the suggested layout of Figure 12. Shortening this path will also reduce the parasitic trace inductance of approximately 25nH/inch. At switch off, this PG 100k TO VIN VCT 500mV/DIV VSHDN 2V/DIV TIME (10ms/DIV) 3435 F09 Figure 9. Power Good PG at 80% VOUT with 100ms Delay PG at VIN > 4V with 100ms Delay VIN VIN 200k 200k PG VOUT = 3.3V LT3435 153k COUT PGFB PG LT3435 PGFB 511k VOUT = 3.3V 200k 12k 165k FB COUT FB 100k CT 100k CT 0.27µF 0.27µF VOUT Disconnect at 80% VOUT with 100ms Delay VOUT Disconnect 3.3V Logic Signal with 100µs Delay VIN VIN 200k 200k PG PG VOUT = 3.3V LT3435 153k PGFB VOUT = 12V LT3435 COUT COUT PGFB 866k 12k FB FB 100k CT 100k CT 0.27µF 270pF 3435 F10 Figure 10. Power Good Circuits 3435fa 19 LT3435 U W U U APPLICATIO S I FOR ATIO parasitic inductance produces a flyback spike across the LT3435 switch. When operating at higher currents and input voltages, with poor layout, this spike can generate voltages across the LT3435 that may exceed its absolute maximum rating. A ground plane should always be used under the switcher circuitry to prevent interplane coupling and overall noise. The VC and FB components should be kept as far away as possible from the switch and boost nodes. The LT3435 pinout has been designed to aid in this. The ground for these components should be separated from the switch current path. Failure to do so will result in poor stability or subharmonic like oscillation. Board layout also has a significant effect on thermal resistance. Pin 8 and the exposed die pad, Pin 17, are a LT3435 4 VIN + VIN L1 SW 2 HIGH FREQUENCY CIRCULATION PATH C2 D1 VOUT C1 LOAD Power dissipation in the LT3435 chip comes from four sources: switch DC loss, switch AC loss, boost circuit current, and input quiescent current. The following formulas show how to calculate each of these losses. These formulas assume continuous mode operation, so they should not be used for calculating efficiency at light load currents. PSW = Figure 11. High Speed Switching Path CONNECT PIN 8 GND TO THE PIN 17 EXPOSED PAD GND L1 C1 D1 MINIMIZE D1-C3 LOOP PLACE VIA's UNDER EXPOSED PAD TO A BOTTOM PLANE TO ENHANCE THERMAL CONDUCTIVITY 2 SW 3 VIN C4 KELVIN SENSE FEEDBACK TRACE AND KEEP SEPARATE FROM BIAS TRACE SHDN 15 LT3435 VIN R1 5 SW FB 12 R2 6 BOOST VC 11 C2 7 CT 8 GND PBOOST 2 VOUT ) (IOUT /46) ( = VIN Quiescent current loss: PQ = VIN (0.0026) + VOUT (0.001) R3 SYNC 14 PGFB 13 4 VIN VIN 2 PGOOD 16 1 NC C3 ( ) (VOUT ) + tEFF (1/2)(IOUT )(VIN)(f) RSW IOUT Boost current loss: D2 VOUT GND THERMAL CALCULATIONS Switch loss: 3435 F11 C2 continuous copper plate that runs under the LT3435 die. This is the best thermal path for heat out of the package. Reducing the thermal resistance from Pin 8 and exposed pad onto the board will reduce die temperature and increase the power capability of the LT3435. This is achieved by providing as much copper area as possible around the exposed pad. Adding multiple solder filled feedthroughs under and around this pad to an internal ground plane will also help. Similar treatment to the catch diode and coil terminations will reduce any additional heating effects. RSW = switch resistance (≈0.15 when hot ) tEFF = effective switch current/voltage overlap time (tr + tf + tIR + tIF) tr = (VIN/1.2)ns tf = (VIN/1.7)ns tIR = tIF = (IOUT/0.2)ns f = switch frequency BIAS 10 CSS 9 C5 GND 3435 F12 Figure 12. Suggested Layout 3435fa 20 LT3435 U W U U APPLICATIO S I FOR ATIO Example: with VIN = 25V, VOUT = 5V and IOUT = 2A: PSW 2 0.15)(2) (5) ( = + 25 0.12 + 0.962 = 1.08 PBOOST = (77e )(12/ )(2)(25)(500e3) –9 / ) (5)2 (240 = 0.03 W 40 PQ = 40(0.0026) + 5(0.001) = 0.11W Total power dissipation is: PTOT = 1.08 + 0.03+ 0.11 = 1.22W Thermal resistance for the LT3435 package is influenced by the presence of internal or backside planes. With a full plane under the FE16 package, thermal resistance will be about 45°C/W. No plane will increase resistance to about 150°C/W. To calculate die temperature, use the proper thermal resistance number for the desired package and add in worst-case ambient temperature: TJ = TA + QJA (PTOT) With the FE16 package (QJA = 45°C/W) at an ambient temperature of 70°C: TJ = 70 + 45(1.22) = 125°C Input Voltage vs Operating Frequency Considerations The absolute maximum input supply voltage for the LT3435 is specified at 60V. This is based solely on internal semiconductor junction breakdown effects. Due to internal power dissipation the actual maximum VIN achievable in a particular application may be less than this. A detailed theoretical basis for estimating internal power loss is given in the section Thermal Considerations. Note that AC switching loss is proportional to both operating frequency and output current. The majority of AC switching loss is also proportional to the square of input voltage. For example, while the combination of VIN = 40V, VOUT = 5V at 2A and fOSC = 500kHz may be easily achievable, simultaneously raising VIN to 60V and fOSC to 700kHz is not possible. Nevertheless, input voltage transients up to 60V can usually be accommodated, assuming the resulting increase in internal dissipation is of insufficient time duration to raise die temperature significantly. A second consideration is controllability. A potential limitation occurs with a high step-down ratio of VIN to VOUT, as this requires a correspondingly narrow minimum switch on time. An approximate expression for this (assuming continuous mode operation) is given as follows: tON(MIN) = VOUT + VF /VIN(fOSC) where: VIN = input voltage VOUT = output voltage VF = Schottky diode forward drop fOSC = switching frequency A potential controllability problem arises if the LT3435 is called upon to produce an on time shorter than it is able to produce. Feedback loop action will lower then reduce the VC control voltage to the point where some sort of cycleskipping or Burst Mode behavior is exhibited. In summary: 1. Be aware that the simultaneous requirements of high VIN, high IOUT and high fOSC may not be achievable in practice due to internal dissipation. The Thermal Considerations section offers a basis to estimate internal power. In questionable cases a prototype supply should be built and exercised to verify acceptable operation. 2. The simultaneous requirements of high VIN, low VOUT and high fOSC can result in an unacceptably short minimum switch on time. Cycle skipping and/or Burst Mode behavior will result causing an increase in output voltage ripple while maintaining the correct output voltage. FREQUENCY COMPENSATION Before starting on the theoretical analysis of frequency response the following should be remembered—the worse the board layout, the more difficult the circuit will be to stabilize. This is true of almost all high frequency analog circuits. Read the Layout Considerations section first. Common layout errors that appear as stability problems are distant placement of input decoupling capacitor and/or 3435fa 21 LT3435 U W U U APPLICATIO S I FOR ATIO catch diode and connecting the VC compensation to a ground track carrying significant switch current. In addition the theoretical analysis considers only first order nonideal component behavior. For these reasons, it is important that a final stability check is made with production layout and components. LT3435 CURRENT MODE POWER STAGE Ω gm = 6 gm = 650µ 11 VC Figure 13 shows the overall loop response with a 330pF VC capacitor and a typical 100µF tantalum output capacitor. The response is set by the following terms: Error amplifier: DC gain is set by gm and RO: Ω EA Gain = 650µ • 1.5M = 975 The pole set by CF and RL: EA Pole = 1/(2π • 1.5M • 470pF) = 220Hz Unity gain frequency is set by CF and gm: EA Unity Gain Frequency = 650µF/(2π • 470pF) = 220kHz Powerstage: DC gain is set by gm and RL (assume 10Ω): PS DC Gain = 6 • 10 = 60 1.5M Ω – FB 12 ESR R2 + 1.25V CF COUT 3435 F13 Figure 13. Model for Loop Response capacitor. As the value of RC is increased, transient response will generally improve but two effects limit its value. First, the combination of output capacitor ESR and a large RC may stop loop gain rolling off altogether. Second, if the loop gain is not rolled off sufficiently at the switching frequency output ripple will perturb the VC pin enough to cause unstable duty cycle switching similar to subharmonic oscillation. This may not be apparent at the output. Small-signal analysis will not show this since a continuous time system is assumed. When checking loop stability the circuit should be operated over the application’s full voltage, current and temperature range. Any transient loads should be applied and the output voltage monitored for a well-damped behavior. 100 80 GAIN (dB) Unity gain set by COUT and gm: 40 0 80 –40 40 PHASE (DEG) 180 VOUT = 3.3V COUT = 100µF, 0.1Ω CF = 470pF 160 RC = 10k CC = 4700pF ILOAD = 1A 120 PS Pole = 1/(2π • 100µF • 10) = 159Hz Tantalum output capacitor zero is set by COUT and COUT ESR CFB R1 CC Pole set by COUT and RL: PS Unity Gain Freq = 6/(2π • 100µF) = 94kHz. OUTPUT 2 ERROR AMP RC The LT3435 uses current mode control. This alleviates many of the phase shift problems associated with the inductor. The basic regulator loop is shown in Figure 12. The LT3435 can be considered as two gm blocks, the error amplifier and the power stage. SW Output Capacitor Zero = 1/(2π • 100µF • 0.1) = 15.9kHz The zero produced by the ESR of the tantalum output capacitor is very useful in maintaining stability. If better transient response is required, a zero can be added to the loop using a resistor (RC) in series with the compensation –80 10 100 1k 10k FREQUENCY (Hz) 100k 0 1M 3435 F14 Figure 14. Overall Loop Response 3435fa 22 LT3435 U PACKAGE DESCRIPTIO FE Package 16-Lead Plastic TSSOP (4.4mm) (Reference LTC DWG # 05-08-1663) Exposed Pad Variation BC 4.90 – 5.10* (.193 – .201) 3.58 (.141) 3.58 (.141) 16 1514 13 12 1110 6.60 ±0.10 9 2.94 (.116) 4.50 ±0.10 6.40 2.94 (.252) (.116) BSC SEE NOTE 4 0.45 ±0.05 1.05 ±0.10 0.65 BSC 1 2 3 4 5 6 7 8 RECOMMENDED SOLDER PAD LAYOUT 4.30 – 4.50* (.169 – .177) 0.09 – 0.20 (.0035 – .0079) 0.50 – 0.75 (.020 – .030) NOTE: 1. CONTROLLING DIMENSION: MILLIMETERS MILLIMETERS 2. DIMENSIONS ARE IN (INCHES) 3. DRAWING NOT TO SCALE 0.25 REF 1.10 (.0433) MAX 0° – 8° 0.65 (.0256) BSC 0.195 – 0.30 (.0077 – .0118) TYP 0.05 – 0.15 (.002 – .006) FE16 (BC) TSSOP 0204 4. RECOMMENDED MINIMUM PCB METAL SIZE FOR EXPOSED PAD ATTACHMENT *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.150mm (.006") PER SIDE 3435fa Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 23 LT3435 RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LT1074/LT1074HV 4.4A (IOUT), 100kHz, High Efficiency Step-Down DC/DC Converters VIN: 7.3V to 45V/64V, VOUT(MIN) = 2.21V, IQ = 8.5mA, ISD < 10µA, DD5/7, TO220-5/7 LT1076/LT1076HV 1.6A (IOUT), 100kHz, High Efficiency Step-Down DC/DC Converters VIN: 7.3V to 45V/64V, VOUT(MIN) = 2.21V, IQ = 8.5mA, ISD < 10µA, DD5/7, TO220-5/7 LT1676 60V, 550mA (ISW), 100kHz, High Efficiency Step-Down DC/DC Converter VIN: 7.4V to 60V, VOUT(MIN) = 1.24V, IQ = 3.2mA, ISD < 2.5µA, S8 LT1765 25V, 3A (ISW), 1.25MHz, High Efficiency Step-Down DC/DC Converter VIN: 3V to 25V, VOUT(MIN) = 1.20V, IQ = 1mA, ISD < 15µA, SO-8, TSSOP16E LT1766 60V, 1.5A (ISW), 200kHz, High Efficiency Step-Down DC/DC Converter VIN: 5.5V to 60V, VOUT(MIN) = 1.20V, IQ = 2.5mA, ISD < 25µA, TSSOP16/E LT1767 25V, 1.5A (ISW), 1.25MHz, High Efficiency Step-Down DC/DC Converter VIN: 3V to 25V, VOUT(MIN) = 1.20V, IQ = 1mA, ISD < 6µA, MS8/E LT1776 40V, 550mA (ISW), 200kHz, High Efficiency Step-Down DC/DC Converter VIN: 7.4V to 40V, VOUT(MIN) = 1.24V, IQ = 3.2mA, ISD < 30µA, N8, S8 LTC®1875 1.5A (IOUT), 550kHz, Synchronous Step-Down DC/DC Converter VIN: 2.7V to 6V, VOUT(MIN) = 0.8V, IQ = 15µA, ISD < 1µA, TSSOP16 LT1940 Dual 1.4A (IOUT), 1.1MHz, High Efficiency Step-Down DC/DC Converter VIN: 3V to 25V, VOUT(MIN) = 1.2V, IQ = 3.8mA, MS10 LT1956 60V, 1.5A (ISW), 500kHz, High Efficiency Step-Down DC/DC Converter VIN: 5.5V to 60V, VOUT(MIN) = 1.20V, IQ = 2.5mA, ISD < 25µA, TSSOP16/E LT1976 60V, 1.5A (ISW), 200kHz, High Efficiency Step-Down DC/DC Converter VIN: 3.3V to 60V, IQ = 100µA, ISD < 1µA LT1977 60V, 1.5A (ISW), 500kHz, High Efficiency Step-Down DC/DC Converter VIN: 3.3V to 60V, IQ = 100µA, ISD < 1µA LT3010 80V, 50mA, Low Noise Linear Regulator VIN: 1.5V to 80V, VOUT(MIN) = 1.28V, IQ = 30µA, ISD < 1µA, MS8E LTC3407 Dual 600mA (IOUT), 1.5MHz, High Efficiency Step-Down DC/DC Converter VIN: 2.5V to 5.5V, VOUT(MIN) = 0.6V, IQ = 40µA, MS10 LTC3412 2.5A (IOUT), 4MHz, Synchronous Step-Down DC/DC Converter VIN: 2.5V to 5.5V, VOUT(MIN) = 0.8V, IQ = 60µA, ISD < 1µA, TSSOP16E LTC3414 4A (IOUT), 4MHz, Synchronous Step-Down DC/DC Converter VIN: 2.25V to 5.5V, VOUT(MIN) = 0.8V, IQ = 64µA, ISD < 1µA, TSSOP20E LT3430 60V, 3A (ISW), 200kHz, High Efficiency Step-Down DC/DC Converter VIN: 5.5V to 60V, VOUT(MIN) = 1.20V, IQ = 2.5mA, ISD < 30µA, TSSOP16E LT3431 60V, 3A (ISW), 500kHz, High Efficiency Step-Down DC/DC Converter VIN: 5.5V to 60V, VOUT(MIN) = 1.20V, IQ = 2.5mA, ISD < 30µA, TSSOP16E LT3433 60V, 400mA (IOUT), 200kHz, Buck-Boost DC/DC Converter VIN: 5V to 60V, VOUT: 3.3V to 20V, IQ = 100µA, TSSOP-16E LT3434 60V, 3A (ISW), 200kHz, High Efficiency Step-Down DC/DC Converter VIN: 3.3V to 60V, IQ = 100µA, ISD < 1µA LTC3727/LTC3727-1 36V, 500kHz, High Efficiency Step-Down DC/DC Controllers VIN: 4V to 36V, VOUT(MIN) = 0.8V, IQ = 670µA, ISD < 20µA, QFN-32, SSOP-28 3435fa 24 Linear Technology Corporation LT 0306 REV A • PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com © LINEAR TECHNOLOGY CORPORATION 2005