LOW VOLTAGE, BOOST DC-DC CONTROLLER August 22, 2000 SC1408 TEL:805-498-2111 FAX:805-498-3804 WEB:http://www.semtech.com DESCRIPTION FEATURES •= 1.8V to 16.5V input range •= Up to 10W output power •= Preset 5V or adjustable output •= Up to 300kHz switching frequency •= 10µA max shutdown current •= Industrial temperature range •= SO-8 or MSOP-8 package The SC1408 is a low voltage boost controller that operates from a 1.8V to 16.5V input range. A shutdown pin allows the user to turn the controller off reducing supply current to less than 2µA typical. Output voltage can be preset to 5V or is adjustable from 3V to 16.5V with a resistor divider. The controller changes frequency in low load conditions to improve efficiency. The SC1408 was designed for two cell Alkaline or single cell Lithium Ion battery applications. With the proper external components it can be used as a boost converter or a buck/boost converter. APPLICATIONS •= PDA Power supplies •= Battery powered applications •= Positive LCD Bias generator •= Portable communications (cellular phones) •= Peripheral card supplies •= Industrial power supplies A current sense is implemented with an external resistor that is not in the load current path. The SC1408 operates in “bootstrapped” mode. When the input voltage to the device is less than 2.5V during startup, a low voltage 50% fixed duty cycle oscillator is switched in to initiate boost action. ORDERING INFORMATION (1) Part Number Package Temp. Range (TA) SC1408IS.TR SO-8 -40° to +85°C SC1408IMS.TR MSOP-8 Note: (1) Only available in tape and reel packaging. A reel contains 2500 devices. TYPICAL APPLICATION - BOOST CONFIGURATION L1 Vin (1.8V to 16.5V) D1 U1 2 4 + 5 C2 7 BST Q1 GATE SHDN ISENSE REF FB GND AGND Vout (3V to 16.5V) R3 1 8 + C3 3 6 R2 R4 SC1408IS C5 1 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 ABSOLUTE MAXIMUM RATINGS Parameter Symbol Maximum Units BST to GND -0.3 to 18 V GND to AGND ±0.1 V -0.3 to VBST+0.3 V -0.3 to min. of VBST+0.3 or 5 V Input Voltage Small Signal Ground to Power Ground GATE to GND FB, SHDN, REF, ISENSE to GND Operating Temperature TA -40 to +85 °C Junction Temperature Range TJ -40 to +150 °C Storage Temperature TSTG -65 to +160 °C TL +300 °C θ=JA 165 206 °C/W θ=JC 40 °C/W Lead Temperature (Soldering) 10 seconds Thermal Resistance, Junction to Ambient SO-8 MSOP-8 Thermal Resistance, Junction to Case SO-8/MSOP-8 ELECTRICAL CHARACTERISTICS (1) Unless specified: VOUT = 5V; ILOAD = 0mA; TA = +25°C PARAMETER SYM CONDITIONS MIN TA = 25°C 1.8 16.5 V TA = -40°C to +85°C 1.8 16.5 V Input Voltage Supply Current Output Voltage TYP MAX UNITS VOUT = 16.5V, SHDN ≤=0.4V TA = -40°C to +85°C 110 140 uA VOUT = 10V, 1.6V ≤=SHDN ≤=5V TA = -40°C to +85°C 2 10 µA VIN = 2.0V to 5.0V, TA = -40°C to +85°C 5.0 5.200 V 4.800 Load Regulation VIN = 2.0V, VOUT = 5V, ILOAD = 0mA to 500mA 60 mV/A Line Regulation VIN = 2.7V to 4.0V, VOUT= 5V, ILOAD = 500mA 7 mV/V Minimum Start Up Voltage No load 1.8 V Maximum Switch On Time TON 9.6 16 22.4 µs Minimum Switch Off Time TOFF 1.4 2.3 3.2 µs VIN = 4V, VOUT = 5V, ILOAD = 500mA Efficiency Reference Voltage VREF IREF = 0µA TA = -40°C to +85°C 87 % 1.176 1.200 1.224 V Reference Load Regulation 0µA < IREF < 100µA -4 10 mV Reference Line Regulation 5V < VOUT < 16.5V 40 100 µV/V FB Trip Point Voltage FB Input Current VFB IFM TA = 25°C TA = -40°C to +85°C TA = 25°C TA = -40°C to +85°C 1.200 1.176 V 1.224 -4 nA +40 2 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 ELECTRICAL CHARACTERISTICS (1) Unless specified: VOUT = 5V; ILOAD = 0mA; TA = +25°C PARAMETER SYM CONDITIONS MIN SHDN Input High Voltage VIH VOUT = 2.7V to 16.5V 1.6 SHDN Input Low Voltage VIL VOUT = 2.7V to 16.5V 0.4 V SHDN Input Current IIN VOUT = 16.5V, SHDN = 0V or 5V +1 µA 100 115 120 mV 0.01 +1 µA Current Limit Trip Level ISENSE Input Current VCS VOUT = 3V to 16.5V TA = 25°C TA = -40°C to +85°C 85 80 ISENSE TYP V GATE Rise Time VOUT = 5V, 1nF from GATE to GND 50 GATE Fall Time VOUT = 5V, 1nF from GATE to GND 50 GATE = high or low 15 GATE On Resistance MAX UNITS ns 30 Ω NOTE: (1) This device is ESD sensitive. Use of standard ESD handling precautions is required. 3 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 BLOCK DIAGRAM REF FB MODE DETECT 1.20V REFERENCE - INTERNAL BIAS + ERROR COMP + - 50mV BIAS SHDN MIN OFF TIME ONE SHOT Q START UP COMP TRIG 2.3uS + - BST S 2.5V Q TRIG Q 16uS MAX ON TIME ONE SHOT GATE R GND LOW VOLTAGE OSCILLATOR CURRENT SENSE AMP + - ISENSE 0.1V AGND PIN CONFIGURATION Top View (SO-8/MSOP-8) PIN DESCRIPTION Pin # Pin Name 1 GATE 2 BST 3 FB 4 SHDN 5 REF 6 AGND 7 GND 8 ISENSE Pin Function Gate drive output. Supply voltage. Voltage feedback. Logic high shuts down the converter. Reference output pin. Small signal analog and digital ground. Power ground. Current sense pin. 4 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 Fig. 1: Typical Application - Boost Configuration L1 Vin=3.3V 22uH D1 COILCRAFT DO3316P-223 Vout=5V B130T R3 31.6k U1 2 C2 100uF + BST 4 SHDN 5 ISENSE REF 7 C5 0.1uF GATE FB GND AGND 1 Q1 IRLR024N C9 (1) + 8 C8 100uF 3 + 6 R2 0.05Ohm R4 10.0k C3 100uF SC1408IS (1) See Component Selection Fig. 2: Typical Application - Buck/Boost (SEPIC) Configuration D2 1N4148 L1A 22uH Vin=2.7V to 6V 2 C1 D1 Vout=5V 100uF 1 + B130T R3 31.6k U1 2 C2 100uF + 4 5 C4 0.1uF 7 C5 0.1uF BST SHDN GATE ISENSE REF FB GND AGND 1 Q1 IRLL3303 C9 (1) + 8 C8 100uF 3 + 6 R2 0.05Ohm 4 L1B 22uH R4 10.0k C3 100uF SC1408IS 3 L1A/L1B IS COUPLED INDUCTOR PULSE PE-53718 OR EQUIVALENT (1) See Component Selection 5 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 Fig. 3: Achieving output voltages greater than 16.5V R6 470 D4 1N4148 L1 22uH D1 3.3V IN 25V OUT B130T R3 200k U1 2 C4 0.1uF C2 100uF + 4 5 7 C5 0.1uF D3 12V BST SHDN GATE FB GND Q1 IRL3103S + C8 100uF 8 ISENSE REF 1 3 + 6 AGND R2 0.05Ohm R4 10.0k C3 100uF SC1408IS Fig. 4: Implementing shutdown with input/output isolation Q2 Si2301DS L1 22uH D1 3.3V IN 12V OUT B130T R5 5.1k U1 2 C4 0.1uF J1 SHORT = RUN OPEN = SHUTDOWN C2 100uF + 4 5 7 1 2 BST SHDN GATE ISENSE REF FB GND AGND SC1408IS 1 R3 90k Q1 IRLL3303 + 8 C8 100uF 3 + 6 R2 0.05Ohm R4 10.0k C3 100uF C5 0.1uF 6 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 THEORY OF OPERATION pin to GND, or to any voltage in the 3.0V to 16.5V range using external divider resistors. The bottom resistor in the divider chain (R4) should be 300kΩ or less and the top resistor (R3 in the application circuits) can be calculated from: The SC1408 is a modified hysteretic boost converter controller. The power switch is turned on when the output voltage falls slightly below it’s setpoint. It remains on for approximately 16µs, or until the inductor current æ V ö reaches limit, whichever occurs first. The power switch is R3 = R 4çç O − 1 then turned off for 2.3µs, or until the output voltage once è VREF again falls below setpoint, whichever occurs last. Inductor The SC1408 is normally powered from the output voltThe SC1408 will work with a wide range of inductor valage. Internal circuitry, such as the bandgap, comparators and one shots will not function properly until the BST ues. A good choice for most applications is 22µH. pin voltage reaches 2.5V. To ensure startup at low input Smaller inductor values result in higher peak currents and increased output ripple, while larger values will revoltages, the normal control circuitry is disabled and a special, low voltage start up oscillator generates an ap- sult in slower loop response. proximate square wave at the GATE pin, initiating boost action. When the output voltage reaches 2.5V, the nor- Transistor Selection mal control circuitry is enabled and the start up oscillator Normally the power switch will be an N-channel MOSFET, although in certain circumstances an NPN bipolar shuts down. may be substituted. To conserve power, a SHDN pin is provided which, when pulled high, shuts down most internal circuitry. The The choice of FET can be critical, especially in battery output voltage will then be one diode drop below the in- powered applications where the converter must be able to use all of the available energy in the battery. This reput. quires that the converter be capable of starting up from COMPONENT SELECTION very low input voltages. For example a two cell alkaline system’s terminal voltage will drop to 1.8V as it apBoost Converter proaches full discharge. For these demanding applicaRSENSE The value of the sense resistor is the primary determin- tions, a FET with low VGS(th) is required. A good rule of ing factor for maximum output current. The SC1408 has thumb is that VGS(th) should be at least 0.5V less than the minimum input voltage. a fixed current limit voltage threshold, which is developed by the peak inductor current flowing through RSENSE. RSENSE may be determined either from the maxi- Diode mum output current curves or from the equation below: For most applications, a Schottky diode should be used as the output rectifier. It will be subjected to reverse voltages of at least VO , and average current will be equal to VCS æ VO + VF − VIN ö ç1 − ÷ IO ( MAX ) = the output current. Industry standard 1N5817 series or RSENSE çè VO + VF − VFET ÷ an equivalent surface mount part would be suitable. t off æ (VIN − VFET )(VO + VF − VIN ) ö ç − 2L çè VO + VF − VFET Output Capacitors Where : Output capacitors should be low ESR to minimize ripple voltage and maximize efficiency. Low ESR tantalums, VF = Output Diode Forward Voltage Drop OSCONs or the newer Polymer capacitors should be VFET = Voltage across FET, R SENSE and Inductor DCR used. Ripple voltage will be approximately: In the equation above, the use of 2.3µs for toff may lead to slightly optimistic current values for low VO/VIN ratios. The theoretical curves use the actual value of toff, VF=0.5V, VFET=0.3V and VCS=0.08V and are generated for L=22µH. Output Voltage Output voltage can be set to 5V by connecting the FB VRIPPLE = VCS * R ESR R SENSE Input Capacitors Input capacitors on a boost converter are less critical than the output capacitors, since there are no fast current pulses drawn from the input supply. A 100µF tantalum will be adequate for most applications. 7 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 Feed Forward Capacitor Although converters based on the SC1408 are stable, with no possibility of oscillation, they are susceptable to “mode switching” at intermediate current levels. This leads to increased ripple voltage and slightly reduced efficiency. Mode switching can be eliminated by a suitable choice of C9. It is possible to empirically select C9. Start with a value of about 100pF and adjust until all low frequency output ripple is eliminated at the desired output current. See AN99-15 “SC1408 Operating Modes” for a full discussion of the origins of “Mode switching” and a more analytical approach to the selection of C9. COMPONENT SELECTION SEPIC Converter RSENSE Again, with the SEPIC topology, the value of the sense resistor is the primary determining factor for maximum output current. The simplest approach to select RSENSE is to add Vin to Vo and use this value as the output voltage in the output current curves or in the equation for Boost converter. Output Voltage Output voltage setting works exactly the same in SEPIC topology as in Boost, including the ability to set to 5V by connecting the FB pin to GND. Care must be taken to ensure that the IC supply (pin2; BST) does not exceed its 16.5V rating. In the circuit of Fig.2: This requires maximum output voltage to be limited to 16.5V-Vin. Higher output voltages are possible with different IC supply strategies. Inductor The SEPIC topology requires a coupled inductor. Again a good choice for most applications is 22uH. Smaller inductor values result in higher peak currents and increase output ripple, while larger values will result in slower loop response. Transistor Selection The choice of FET can be critical, especially in battery powered applications where the converter must be able to use all of the available energy in the battery. This requires that the converter be capable of starting up from very low input voltages. For example a two cell alkaline system’s terminal voltage will drop to 1.8V as it approaches full discharge. For these demanding applications, a FET with low VGS(th) is required. A good rule of thumb is that VGS(th) should be at least 0.5V less than the minimum input voltage. Diode For most applications, a Schottky diode should be used as the output rectifier. It will be subjected to reverse voltages of at least VO +VIN and average current equal to the output current. Industry standard 1N5817 series or an equivalent surface mount part would be suitable. Output Capacitors Output capacitors should be low ESR to minimize ripple voltage and maximize efficiency. Low ESR tantalums, OSCONs or the newer Polymer capacitors should be used. Input Capacitors Input capacitors on a SEPIC converter are less critical than the output capacitors, since there are no fast current pulses drawn from the input supply. A 100µF tantalum will be adequate for most applications. Series Capacitors The Series capacitor(s) must be capable of handling an RMS current given by:IRMS = IO VO + 0.5 VIN Feed Forward Capacitor The feed forward capacitor should be selected in the same way as for a Boost application. LAYOUT GUIDELINES The SC1408 is fairly insensitive to layout, however following some simple guidelines will help ensure successful implementation. Whenever possible, lay the circuitry out over a ground plane. Connect AGND and GND together at the IC and return to the ground plane with one or two vias. Place the current sense resistor (R2), the REF decoupling capacitor (C5) and the divider resistors (R3 and R4) close to the IC, Return the ground side of these components to the ground plane close to the AGND/GND pin vias. Connect the top side of the sense resistor to ISENSE with a short trace and the source of Q1 directly to the sense resistor. Make the output loop Q1, D1 and the output capacitors (C3, C8) as small as possible to minimize EMI. 8 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 3.5 3.5 Vo=3.3V L=22uH 3.0 Vo=5V L=22uH 3.0 20mOhm 2.5 20mOhm 2.5 25mOhm 2.0 1.5 35mOhm 1.0 50mOhm 0.5 Io (A) Io (A) 25mOhm 35mOhm 1.5 50mOhm 1.0 0.5 100mOhm 100mOhm 0.0 0.0 2.0 2.2 2.4 2.6 Vin (V) 2.8 3.0 2.0 3.2 3.5 2.5 3.0 3.5 Vin (V) 4.0 4.5 5.0 4.0 Vo=12V L=22uH 3.0 Vo=15V L=22uH 3.5 20mOhm 20mOhm 3.0 2.5 25mOhm 2.0 35mOhm 1.5 1.0 50mOhm 0.5 100mOhm 2.5 Io (A) Io (A) 2.0 25mOhm 2.0 1.5 35mOhm 1.0 50mOhm 0.5 100mOhm 0.0 0.0 2.0 4.0 6.0 8.0 10.0 12.0 2.0 4.0 6.0 8.0 Vin (V) 10.0 Vin (V) 12.0 14.0 16.0 Figs. 5 - 8: Maximum output current vs. input voltage and sense resistor value. (Boost Mode) 100% 100% Vo=5V Vo=12V 90% Efficiency (%) Efficiency (%) 90% 80% Vin=5.0V Vin=4.0V Vin=3.3V Vin=3.0V 70% 80% Vin=5.0V Vin=3.0V Vin=1.8V 70% 60% 60% 1 10 100 1000 1 10 100 1000 Io (mA) Io (mA) 100% Vo=15V Efficiency (%) 90% 80% Vin=12V Vin=9.0V Vin=5.0V Vin=3.0V Vin=1.8V 70% 60% 1 10 100 1000 Io (mA) Figs. 9-11:Efficiency in the Boost Application circuit of Fig.1 9 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 Output Ripple Voltage; Vin=3V, Vo=5V, Io=470mA Output Ripple Voltage; Vin=3V, Vo=5V, Io=810mA Ch1 = Output Ripple Ch1 = Output Ripple Ch2 = Voltage at GATE pin Ch2 = Voltage at GATE pin Load Transient; Vin=3V, Vo=5V, Io=0 to 500mA Load Transient; Vin=2V, Vo=5V, Io=0 to 500mA Ch1 = Output Voltage Ch1 = Output Voltage Ch2 = Load Current (0.5A/div) Ch2 = Load Current (0.5A/div) 10 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 OUTLINE DRAWING - SO-8 JEDEC REF: MS-012AA LAND PATTERN - SO-8 11 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320 LOW VOLTAGE, BOOST DC-DC CONTROLLER SC1408 August 22, 2000 OUTLINE DRAWING - MSOP-8 LAND PATTERN - MSOP-8 ECN00-1275 12 © 2000 SEMTECH CORP. 652 MITCHELL ROAD NEWBURY PARK CA 91320