SC1109 Synchronous PWM Controller with Dual Low Dropout Regulator Controllers POWER MANAGEMENT Description Features Dual linear controllers LDOs track input voltage within 200mV (function of The SC1109 was designed for the latest high speed motherboards. It combines a synchronous voltage mode controller (switching section) with two low-dropout linear regulator controllers. The voltage mode controller provides the power supply for the system AGTL bus. The Dual linear controllers power the chip set and clock circuitry. the MOSFETs used) until regulation Integrated drivers Power good signal (SC1109A, SC1109B) Soft start Lossless current sense Programmable over current limit (SC1109C) 200kHz (SC1109A, SC1109C), and 500kHz (SC1109B) fixed frequency. The SC1109A switching section features lossless current sensing, while SC1109C provides programmable over current limit. SC1109 also utilizes latched driver outputs for enhanced noise immunity. SC1109A and SC1109C operate at a fixed frequency of 200kHz, and the SC1109B is available at a fixed frequency of 500kHz. The VTT output voltage is internally fixed at 1.2V Applications Pentium(R) III Motherboards Triple power supplies The SC1109 linear sections are low dropout regulators designed to track the 3.3V power supply when it turns on or off. The voltage for the linear controllers LDO1, and LDO2 are 1.8V/1.5V. Typical Application Circuit 12V IN 5V STBY C1 0.1uF 5V IN C2 2x1500uF SC1109ACSTR or SC1109BCSTR C3 0.1uF + 11 C5 0.1uF 4 C6 0.1uF 5 14 12 POWER GOOD 13 C9 0.1uF 15 16 VCC BCAP+ 10 BST 9 DH BCAPSS/EN 8 DL VOSENSE GATE1 LDOS2 LDOS1 1.2V 6A C7 3x1500uF Q2 MOSFET N R2 2.2 VTT C8 0.1uF + 6 GND GATE2 Q1 MOSFET N L1 4uH R1 2.2 7 PHASE PWRGD C4 0.1uF 3 STBY 2 1 U1 3.3V IN + Q3 MOSFET N C10 330uF + Q4 MOSFET N LDO1 = 1.8V LDO2 = 1.5V C11 330uF C12 330uF + 12V IN 5V STBY C1 0.1uF 5V IN C2 2x1500uF + C3 0.1uF U1 C13 1nF 11 R3 TBD C5 0.1uF 4 C6 0.1uF 5 14 12 OCSET C9 0.1uF 13 15 16 VCC STBY BCAP+ BST DH BCAP- PHASE 10 9 DL VOSENSE GND GATE2 GATE1 LDOS2 LDOS1 R1 2.2 7 SS/EN OCSET C4 0.1uF 3 8 R2 2.2 Q1 MOSFET N L1 4uH 1.2V 6A C7 Q2 3x1500uF MOSFET N VTT C8 0.1uF + 6 2 1 SC1109CCSTR 3.3V IN + Q3 MOSFET N C10 330uF + Revision: May 13, 2004 C11 330uF 1 Q4 MOSFET N LDO1 = 1.8V LDO2 = 1.5V + C12 330uF www.semtech.com SC1109 POWER MANAGEMENT Absolute Maximum Ratings Exceeding the specifications below may result in permanent damage to the device, or device malfunction. Operation outside of the parameters specified in the Electrical Characteristics section is not implied. Parameter Symbol Maximum Units VCC to GND -0.3 to +7 V STBY to GND -0.3 to +7 V BST to GND -0.3 to +20 V PHASE to GND -1 to +15 V LDOSx -0.3 to 5 V Operating Temperature Range TA 0 to +70 C Junction Temperature Range TJ 0 to +125 C Storage Temperature Range TSTG -65 to +150 C Lead Temperature (Soldering) 10 Seconds TL 300 C Thermal Resistance Junction to Ambient JA 130 C/W Thermal Impedance Junction to Case JC 30 C/W Electrical Characteristics Unless specified: VOSENSE = VO; Vcc=4.75V to 5.25V; STBY=4.75V to 5.25V; BST = 11.4V to 12.6V; TA = 0 to 70C Parameter Symbol Conditions MIN T YP MAX UNIT S 4.4 5 5.25 V 8 12 mA 20 mA 1.212 V Supply (VCC) Supply Voltage VCC Supply Quiescent Current ICCQ VCC = 5V, SS/EN = 0V ICC VCC = 5V, SS/EN > 1V VTT IO = 2A Load Regulation((1) LOADREG IO = 0A to 6A Line Regulation LINEREG Vin = 4.75V to 5.25V Supply Operating Current (1) Switching Section Output Voltage (1) (1) Oscillator Frequency fOSC Oscillator Max Duty Cycle Current Limit trip (Vin-VPHASE) OscillatorGain (AOL) (3) 1.188 1.200 1 % 0.15 % SC1109A 175 200 225 kHz SC1109B 450 500 550 kHz SC1109C 175 200 225 kHz 90 95 D % SC1109A 180 200 220 mV SC1109B 180 200 220 mV ItripIlimit SC1109C 112 160 208 uA GAINVTT VOSENSE to VO VtripIlimit 35 dB Under Voltage Lock Out Threshold VCCHIGH Hysteresis VCCHYST 3.9 4.1 4.4 200 V mV Power Good Power Good Threshold Voltage 88 PGth 112 % Soft Start / Enable SS/EN Source current SS/EN Sink current (2) Shutdown Voltage 2004 Semtech Corp. (2) IsourceSS/EN VSS/EN = 1.5V 5 10 12 A IsinkSS/EN VSS/EN = 1.5V 1 2 3 A 650 mV VSS/EN 600 2 www.semtech.com SC1109 POWER MANAGEMENT Electrical Characteristics (Cont.) Unless specified: VOSENSE = VO; Vcc=4.75V to 5.25V; STBY=4.75V to 5.25V; BST = 11.4V to 12.6V; TA = 0 to 70C Parameter Symbol Conditions MIN TYP MAX UNITS IsourceDH BST-DH = 4.5V 500 mA DH-PHASE = 3.1V 500 mA DH-PHASE = 1.5V 100 mA VCC-DL = 4.5V 500 mA DL-GND = 3.1V 500 mA DL-GND = 1.5V 100 mA Internal Drivers Peak DH Source Current Peak DH Sink Current Peak DL Source Current IsinkDH IsourceDL Peak DL Sink Current IsinkDL Dead time TDEAD 40 100 Standby Voltage VSTBY 4.4 5 Standby Quiescent current ISTDBYQ ns Linear Sections Tracking Difference(1)(4) VSTBY = 5V, SS/EN = 0V DeltaTRACK 5.25 V 9 mA 200 mV Output Voltage LDO1 VLDO1 IO = 0 to 4A, Vin = 3.3V 1.782 1.818 1.854 V Output Voltage LDO2 VLDO2 IO = 0 to 4A, Vin = 3.3V 1.470 1.500 1.530 V Load Regulation LOADREG IO = 0 to 4A, Vin = 3.3V 0.3 % Line Regulation LINEREG Io = 2A, Vin = 3.13V to 3.47V 0.3 % LDOS(1,2) Input Impedance(3) Gain (AOL)(3) ZIN GAINLDO 10 LDOS (1,2) to GATE (1,2) k 50 dB Notes: (1) All electrical characteristics are for the application circuit on page 16. (2) Soft start function is performed after Vcc is above the UVLO and SS/EN is above 600mV. The Soft start capacitor is then charged at a 10uA constant current until SS/EN is charged to above 1V. (3) Guaranteed by design (4) Tracking Difference is defined as the delta between 3.3V Vin and the LDO1, LDO2 output voltages during the linear ramp up until regulation is achieved. The tracking voltage difference might vary depending on MOSFETs RdSON, and load conditions. (5) This device is ESD sensitive. Use of standard ESD handling precautions is required. 2004 Semtech Corp. 3 www.semtech.com SC1109 POWER MANAGEMENT Pin Configuration Top View LDOS1 GATE1 STBY BCAP+ BCAPGND PHASE DL 1 16 2 15 3 14 4 13 5 12 6 11 7 10 8 9 Top View LDOS2 GATE2 SS/EN VOSENSE PWRGD VCC BST DH LDOS1 GATE1 STBY BCAP+ BCAPGND PHASE DL (SC1109A/B) 16 2 15 3 14 4 13 5 12 6 11 7 10 8 9 LDOS2 GATE2 SS/EN VOSENSE OCSET VCC BST DH (SC1109C) Ordering Information Part Number (1) P ackag e Linear Voltage PWM Frequency Over Current set Temp Range (TJ) SC1109ACSTR SO-16 1.8V/1.5V 200kHz Internal 0 to 125C SC1109BSTR SO-16 1.8V/1.5V 500kHz Internal 0 to 125C SC1109CSTR SO-16 1.8V/1.5V 200kHz External 0 to 125C SC1109EVB 1 Evaluation Board Note: (1) Only available in tape and reel packaging. A reel contains 2500 devices. Pin Descriptions Pin # Pin Name Pin Function 1 LDOS1 Sense Input for LDO1. 2 GATE1 Gate Drive Output LDO1 (1.8V). 3 STBY 5V Standby Input, supplies power for Ref, Charge Pump, Oscillator and FET controllers. Should be present prior to other voltages and switched off last. 4 BC AP+ Positive Connection to Boost Capacitor. 5 BC AP- Negative Connection to Boost Capacitor. 6 GND 7 PHASE 8 DL Low Side Driver Output. 9 DH High Side Driver Output. 10 BST Boost Input. 11 VC C Power Supply Input. 12 PWRGD Open Colector Power Good Flag for 1.2V Outpu t(SC1109A, and SC1109B). OCSET Over current set pin for the PWM (SC1109C). A resistor to the Mosfe'ts supply will program the over current level. Ground. Phase Node. 13 VOSENSE 14 SS/EN Soft Start/Enable. 15 GATE2 Gate Drive output LDO2 (1.5V). 16 LDOS2 Sense Input for LDO2. 2004 Semtech Corp. Output Sense Input for 1.2V Output. 4 www.semtech.com SC1109 POWER MANAGEMENT Block Diagram VCC VBG 200mV UVLO 1.2V + Bandgap OVER CURRENT - + - BST -10% +10% HIGH SIDE DRIVE DH - PWRGD + PHASE OSCILLATOR SHOOT THRU CONTROL + PWM VOSENSE VCC R Q + + VBG VCC - ERROR AMP LOW SIDE DRIVE S SET DOMINATES S SC1109A/B 10uA Q 0.8V + SS/EN - SS/EN GND R HICCUP LATCH FAULT + 0.6V DL LOW SIDE OFF 5VSTBY 2uA 5VSTBY VBG + GATE2 5VSTBY LDOS2 5VSTBY CHARGE PUMP STBY VBG OSCILLATOR + GATE1 - BCAP+ LDOS1 BCAP- VCC 160uA VBG UVLO 1.2V + Bandgap OVER CURRENT - OCSET + - BST HIGH SIDE DRIVE DH PHASE OSCILLATOR SHOOT THRU CONTROL PWM VOSENSE VCC SC1109C R Q + + VBG VCC - ERROR AMP LOW SIDE DRIVE S SET DOMINATES S 10uA 0.8V SS/EN SS/EN Q + - GND R HICCUP LATCH FAULT + 0.6V DL LOW SIDE OFF 5VSTBY 2uA 5VSTBY VBG + GATE2 5VSTBY LDOS2 5VSTBY CHARGE PUMP STBY OSCILLATOR VBG + - BCAP+ GATE1 LDOS1 BCAP- Marking Information SC1109ACS yyww xxxxx yyww xxxxx SC1109A SC1109BS yyww xxxxx SC1109B SC1109CS yyww xxxxx SC1109C = Datecode (Example: 9912) = Semtech Lot # (Example: 90101) 2004 Semtech Corp. 5 www.semtech.com SC1109 POWER MANAGEMENT Application Information THEORY OF OPERATION The gate drive status stays the same until the capacitors voltage reaches 1V, when the error amplifier output starts to cross the oscillator triangular ramp of 1V to 2V. The SC1109 has integrated a synchronous buck controller and two Low drop out regulator controllers into a 16 Pin SOIC package. The switching regulator provides a 1.2V (VTT) bus termination voltage for use in AGTL (Assisted Gunning Transceiver Logic), while the dual LDO regulators provide 1.5V, and 1.8V to power up the Chip set and the Clock circuitry used in Pentium(R) III Motherboards. As the SS/EN pin continues to rise, the error amplifier output also rises at the same rate and the duty cycle increases. Once the VTT output has reached regulation and is within 1.2V 12% , an open collector power good flag is activated, and the error amplifier output will no longer be clamped to the SS/EN voltage and will stay between 1V to 2V and maintain regulation of 1%. The SS/EN voltage continues to rise up to 2.5V and will stay at that voltage level during normal operation. SUPPLIES Two supplies, VSTBY, and VCC are used to power the SC1109 . VSTBY supply provides the bias for the Internal Reference, Oscillator, and the LDO FET controllers. This supply should always be brought up first and turned off last in accordance with PC power configuration requirements. The VCC supply provides the bias for the Power Good circuitry, and the high side FET Rdson sensing/ over current circuitry, VCC also is used to drive the low side MOSFET gate. An external 12V supply or a classical boot strapping technique can provide the gate drive for the upper Mosfet. Vcc PowerGood PWM CONTROLLER Soft start SC1109 is a voltage mode buck controller that utilizes an internally compensated high bandwidth error amplifier to sense the VTT output voltage. External compensation components are not needed and a stable closed loop response is insured due to the internal compensation. PhaseNode If an over current condition occurs, the SS/EN pin will discharge by a 2A current source, from 2.5V to 800mV. During this time both DH, and DL will be turned off. Once the SS/EN reaches 800mV, the low side gate will be turned on, and the SS/EN pin will again start to be charged by the 10A current source, and the same soft start sequence mentioned above will be repeated. START UP SEQUENCE Initially during the power up, the SC1109 is in under voltage lockout condition. The latch (SET dominant) in the hiccup section is set , and the SS/EN pin is pulled low by the 2A soft start current source. Mean while, the high side and low side gate drivers DH, and DL are kept low. Once the VCC exceeds the UVLO threshold of 4.2V, the latch is reset and the external soft start capacitor starts to be charged by a 10A current source. OVER CURRENT SC1109A/B monitor the Upper MOSFETs Rdson voltage drop due to an over current condition. This method of current sensing minimizes any unnecessary losses due to external sense resistance. The gate drives are still kept off until the soft start capacitors voltage rises above 600mV, when the low side gate is turned on, and the high side gate is kept off. 2004 Semtech Corp. 6 www.semtech.com SC1109 POWER MANAGEMENT Application Information (Cont.) GATE DRIVERS An internal comparator with a 200mV reference monitors the Drop across the upper FET, Once the Vdson of the MOSFET exceeds the 200mV limit, the low side gate is turned on and the upper FET is turned off. Also an internal latch is set and the soft start capacitor is discharged. Once the lower threshold of the soft start circuit is crossed, the same softstart sequence mentioned previously is repeated. This sequence is repeated until the over condition is removed. The Low side gate driver is supplied from VCC and provide a peak source/sink current of and 500mA. The high side gate drive is also capable of sourcing and sinking peak currents of 500mA. The high side MOSFET gate drive can be provided by an external 12V supply that is connected from BST to GND. The actual gate to source voltage of the upper MOSFET will approximately equal 7V (12V-VCC). If the external 12V supply is not available, a classical boot strap technique can be implemented from the VCC supply. A boot strap capacitor is connected from BST to Phase while VCC is connected through a diode (Schottky or other fast low VF diode) to the BST. This will provide a gate to source voltage approximately to VCC-Vdiode drop. Upper Gate Lower Gate PhaseNode Low er Gat e Low er Gat e PhaseNode Vtt Sho rted Shoot through control circuitry provides a 100ns dead time to ensure both upper and lower MOSFET will not turn on simultaneously and cause a shoot through condition. Upper Gate Lo wer Gate DUAL LDO CONTROLLERS SC1109 also provides two low drop out linear regulator controllers that can be used to generate a 1.8V and a 1.5V output. The LDO output voltage is achieved by controlling the voltage drop across an external MOSFET from a 3.3V supply voltage. The SC1109C utilizes an internal current source and an external resistor connected from the OCSET pin to the Mosfet's supply to program a current limit level. This limit is programmable by choosing the resistor according to the level required. To reduce any noise pick up a 1nF capacitor should be placed across the programing resistor. The device operation is similar to the SC1109A/B during the over current condition as mentioned above. 2004 Semtech Corp. The output voltage is sensed at the LDOS pin of the SC1109 and compared to an internal reference. The gate drive to the external MOSFET is then adjusted until regulation is achieved. In order to have sufficient voltage to the gate drives of the external MOSFET, an internal charge pump is utilized to boost the gate drive voltage to about two times the VSTBY. 7 www.semtech.com SC1109 POWER MANAGEMENT Application Information (Cont.) LAYOUT GUIDELINES Careful attention to layout requirements are necessary for successful implementation of the SC1109 PWM controller. High currents switching are present in the application and their effect on ground plane voltage differentials must be understood and minimized. 1). The high power parts of the circuit should be laid out first. A ground plane should be used, the number and position of ground plane interruptions should be such as to not unnecessarily compromise ground plane integrity. Isolated or semi-isolated areas of the ground plane may be deliberately introduced to constrain ground currents to particular areas, for example the input capacitor and bottom FET ground. 2). The loop formed by the Input Capacitor(s) (Cin), the Top FET (Q1) and the Bottom FET (Q2) must be kept as small as possible. This loop contains all the high current, fast transition switching. Connections should be as wide and as short as possible to minimize loop inductance. Minimizing this loop area will a) reduce EMI, b) lower ground injection currents, resulting in electrically "cleaner" grounds for the rest of the system and c) minimize source ringing, resulting in more reliable gate switching signals. 3). The connection between the junction of Q1, Q2 and the output inductor should be a wide trace or copper region. It should be as short as practical. Since this connection has fast voltage transitions, keeping this connection short will minimize EMI. Also keep the Phase connection to the IC short, top FET gate charge currents flow in this trace. The internal charge pump charges an external Bucket capacitor to VSTBY and then connects it in series with VSTBY to the LDOs supply at a frequency of about 200kHz. This ensures sufficient gate drive voltage for the LDOs independent of the VCC or the 12V external supply being available due to start up timing sequence from the silver box. 3.3V Vin 1.8V Vout 1.5V Vout The LDO1, and LDO2 output voltages are forced to track the 3.3V input supply. This feature ensures that during the start up application of the 3.3V, the LDO1, and LDO2 outputs track the 3.3V within 200mV typical until regulation is achieved. However, the VSTBY should be established at least 500us, to allow the charge pump to reach its maximum voltage, before the linear section will track within 200mV. This tracking will sequence the correct start up timing for the external Chipset and Clock circuitry. 12V IN 5V STBY 5V IN U4 SC1109A VCC BCAP+ STBY + BST DH BCAP- PHASE VTT SS/EN PWRGD VOSENSE DL + GND GATE2 GATE1 LDOS2 LDOS1 3.3V IN Heavy Lines indicate high current paths. 1.5V + 2004 Semtech Corp. C10 330uF 1.8V + + 8 www.semtech.com SC1109 POWER MANAGEMENT Application Information (Cont.) 6) BST for the SC1109 should be supplied from the 12V supply, the BST pin should be decoupled directly to GND by a 0.1mF ceramic capacitor, trace lengths should be as short as possible. If a 12V supply is not available, a classical boot strap method could be implemented to achieve the upper MOSFETs gate drive. 7) The Phase connection should be short . 8) Ideally, the grounds for the two LDO sections should be returned to the ground side of (one of) the output capacitor(s). 4) The Output Capacitor(s) (Cout) should be located as close to the load as possible, fast transient load currents sre supplied by Cout only, and connections between Cout and the load must be short, wide copper areas to minimize inductance and resistance. 5) The SC1109 is best placed over a quiet ground plane area, avoid pulse currents in the Cin, Q1, Q2 loop flowing in this area. GND should be returned to the ground plane close to the package and close to the ground side of (one of) the output capacitor(s). If this is not possible, the GND pin may be connected to the ground path between the Output Capacitor(s) and the Cin, Q1, Q2 loop. Under no circumstances should GND be returned to a ground inside the Cin, Q1, Q2 loop. 5V + Vout + 2004 Semtech Corp. 9 www.semtech.com SC1109 POWER MANAGEMENT Application Information (Cont.) COMPONENT SELECTION SWITCHING SECTION OUTPUT CAPACITORS - Selection begins with the most critical component. Because of fast transient load current requirements in modern microprocessor core supplies, the output capacitors must supply all transient load current requirements until the current in the output inductor ramps up to the new level. Output capacitor ESR is therefore one of the most important criteria. The maximum ESR can be simply calculated from: RESR Vt It Where Vt = Maximum transient voltage excursion It = Transient current step For example, to meet a 100mV transient limit with a 10A load step, the output capacitor ESR must be less than 10m. To meet this kind of ESR level, there are three available capacitor technologies. Technology Each Capacitor C (uF) ESR (m) Low ESR Tantalum 330 60 OS-CON 330 Low ESR Aluminum 1500 L The calculated maximum inductor value assumes 100% duty cycle, so some allowance must be made. Choosing an inductor value of 50 to 75% of the calculated maximum will guarantee that the inductor current will ramp fast enough to reduce the voltage dropped across the ESR at a faster rate than the capacitor sags, hence ensuring a good recovery from transient with no additional excursions. We must also be concerned with ripple current in the output inductor and a general rule of thumb has been to allow 10% of maximum output current as ripple current. Note that most of the output voltage ripple is produced by the inductor ripple current flowing in the output capacitor ESR. Ripple current can be calculated from: = I L RIPPLE V IN 4 L f OSC Ripple current allowance will define the minimum permitted inductor value. C (uF) ESR (m) 6 2000 10 25 3 990 8.3 44 5 7500 8.8 TOP FET - The power dissipation in the top FET is a combination of conduction losses, switching losses and bottom FET body diode recovery losses. a) Conduction losses are simply calculated as: P COND The choice of which to use is simply a cost/performance issue, with Low ESR Aluminum being the cheapest, but taking up the most space. INDUCTOR - Having decided on a suitable type and value of output capacitor, the maximum allowable value of inductor can be calculated. Too large an inductor will produce a slow current ramp rate and will cause the output capacitor to supply more of the transient load current for longer - leading to an output voltage sag below the ESR excursion calculated above. 2004 Semtech Corp. R ESR C (VIN - V O ) It POWER FETS - The FETs are chosen based on several criteria with probably the most important being power dissipation and power handling capability. Total Qty Rqd. The maximum inductor value may be calculated from: 2 = IO R DS ( on ) where = duty cycle VO V IN b) Switching losses can be estimated by assuming a switching time, if we assume 100ns then: P SW 10 = I O V IN 10 -3 www.semtech.com SC1109 POWER MANAGEMENT Application Information (Cont.) or more generally, IO VIN ( t r + t f ) fOSC 4 c) Body diode recovery losses are more difficult to estimate, but to a first approximation, it is reasonable to assume that the stored charge on the bottom FET body diode will be moved through the top FET as it starts to turn on. The resulting power dissipation in the top FET will be: PSW = P RR = Q RR V IN f OSC To a first order approximation, it is convenient to only consider conduction losses to determine FET suitability. For a 5V in; 2.8V out at 14.2A requirement, typical FET losses would be: FET Type RDS(on) (m) PD(W) Package IRL3402S 15 1.33 D2PAK IRL2203 10.5 0.93 D2PAK Si4410 20 1.77 SO-8 Each of the package types has a characteristic thermal impedance, for the TO-220 package, thermal impedance is mostly determined by the heatsink used. For the surface mount packages on double sided FR4, 2 oz printed circuit board material, thermal impedances of 40oC/W for the D2PAK and 80oC/W for the SO-8 are readily achievable. The corresponding temperature rise is detailed below: Using 1.5X Room temp RDS(ON) to allow for temperature rise. FET Type RDS(on) (m) PD(W) Package IRL3402S 15 1.69 D2PAK IRL2203 10.5 1.19 D2PAK Si4410 20 2.26 SO-8 BOTTOM FET - Bottom FET losses are almost entirely due to conduction. The body diode is forced into conduction at the beginning and end of the bottom switch conduction period, so when the FET turns on and off, there is very little voltage across it, resulting in low switching losses. Conduction losses for the FET can be determined by: P COND 2 = IO R For the example above: 2004 Semtech Corp. DS ( on ) (1 - ) Temperature rise ( 0C) FET Type Top FET Bottom FET IRL3402S 67.6 53.2 IRL2203 47.6 37.2 Si4410 180.8 141.6 It is apparent that single SO-8 Si4410 are not adequate for this application, but by using parallel pairs in each position, power dissipation will be approximately halved and temperature rise reduced by a factor of 4. INPUT CAPACITORS - since the RMS ripple current in the input capacitors may be as high as 50% of the output current, suitable capacitors must be chosen accordingly. Also, during fast load transients, there may be restrictions on input di/dt. These restrictions require useable energy storage within the converter circuitry, either as extra output capacitance or, more usually, additional input capacitors. Choosing low ESR input capacitors will help maximize ripple rating for a given size. 11 www.semtech.com SC1109 POWER MANAGEMENT SC1109 Gain & Phase Margin SC1109A Gain & Phase Margin 50 200 180 40 160 Gain 20 140 120 Phase Margin 10 100 80 Phase Margin (Deg.) Gain (dB) 30 0 60 -10 40 -20 10 100 1,000 10,000 20 100,000 frequency(Hz) Typical VTT Gain/Phase plot at Vin = 5V, Iout = 3A 2004 Semtech Corp. 12 www.semtech.com SC1109 POWER MANAGEMENT Typical Characteristics SC1109 Quiescent Current (Linear) vs Ta SC1109 Quiescent Current vs Ta 7.90 4.40 Vcc = 4.75 7.80 4.35 7.75 4.30 ISTBYQ (mA) Icc (mA) 4.45 Vcc = 5.25 7.85 7.70 7.65 7.60 4.25 4.20 4.15 7.55 4.10 7.50 4.05 7.45 4.00 7.40 3.95 0 10 20 30 40 50 60 Vcc = 5.25 Vcc = 4.75 0 70 10 20 40 50 60 70 60 70 Ta (C.) Ta (C.) Typical ISTBYQ (Linear section) Typical Icc (Switching section) SC1109 Soft start Source Current vs Ta SC1109 Soft start Source Current vs Ta 9.32 8.10 Vcc = 5.25V , Vss = 0V 9.30 30 Vcc = 4.75V , Vss = 1.5V 8.08 Vcc = 4.75V , Vss = 0V Vcc = 5.25V , Vss = 1.5V 9.28 8.06 9.26 Iss (uA) Iss (uA) 8.04 9.24 9.22 8.02 8.00 9.20 7.98 9.18 7.96 9.16 9.14 7.94 0 10 20 30 40 50 60 70 0 10 20 30 Ta (C.) 50 Typical Soft start source Current Vss = 1.5V Typical Soft start source Current Vss = 0V SC1109 Soft start Sink Current vs Ta SC1109 Soft start Sink Current vs Ta 1.80 9.30 Vcc = 5.25V , Vss = 0V 9.28 9.26 Vcc = 4.75V , Vss = 1.5V 1.79 Vcc = 4.75V , Vss = 0V Vcc = 5.25V , Vss = 1.5V 9.24 1.79 Iss (uA) 9.22 Iss (uA) 40 Ta (C) 9.20 9.18 9.16 1.78 1.78 9.14 9.12 1.77 9.10 1.77 9.08 0 10 20 30 40 50 60 0 70 20 30 40 50 60 70 Typical Soft start sink Current Vss = 1.5V Typical Soft start sink Current Vss = 0V 2004 Semtech Corp. 10 Ta (C.) Ta (C.) 13 www.semtech.com SC1109 POWER MANAGEMENT Typical Characteristics SC1109 Tracking Difference (Io LDO1,2 = 2A) vs Ta 280.0 260.0 Delta (mV) 240.0 220.0 200.0 180.0 LDO2 Vcc = 4.75 LDO2 Vcc = 5.25 LDO1 Vcc = 4.75 LDO1 Vcc = 5.25 160.0 0 10 20 30 40 50 60 70 Ta (C.) Typical Tracking difference (BetweenVin3.3 & LDO) 2004 Semtech Corp. 14 www.semtech.com SC1109 POWER MANAGEMENT Typical Characteristics SC1109 (VTT) Line Reg. vs Vin (Iout = 6.0A) SC1109 (VTT) Eff. vs Iout (Vin = 5.0V) 90.0% 0.350% 80.0% 0.300% Line Reg.(%) Efficiency(%) 70.0% 60.0% 50.0% 40.0% 30.0% 20.0% IRL3103R(V1.8,V2.5 No load) 2.00 4.00 6.00 0.200% 0.150% 0.100% 0.050% 10.0% 0.0% 0.00 0.250% IRL3103R(V1.8,V2.5 No load) 0.000% 4.000 4.500 5.000 5.500 8.00 Iout_Vtt (Amps) Typical VTT Efficiency at Vin=5V Typical VTT Line Regulation at Iout = 6 Amps SC1109 (VTT) Line Reg. vs Vin (Iout = 3.0A) 0.000% 0.120% -0.100% 0.100% -0.200% 0.080% Line Reg.(%) Load Reg.(%) SC1109 (VTT) Load Reg. vs Iout (Vin = 5.0V) -0.300% -0.400% -0.500% -0.600% 0.00 4.00 0.060% 0.040% 6.00 0.000% 4.700 4.800 8.00 4.900 5.000 5.100 5.200 5.300 Vin (V) Iout_Vtt (Amps) Typical VTT Line Regulation at Iout = 3 Amps Typical VTT Load Regulation at Vin=5V 2004 Semtech Corp. IRL3103R(V1.8,V2.5 No load) 0.020% IRL3103R(V1.8,V2.5 No load) 2.00 6.000 6.500 7.000 Vin (V) 15 www.semtech.com SC1109 POWER MANAGEMENT Evaluation Board Schematic 12V IN J1 GND J2 5V STBY J3 GND J4 5V IN J5 C1 0.1uF 5V IN J6 C2 1500uF C5 R1 10k R5 0 C3 0.1uF + 11 C6 0.1uF + 1500uF GND 4 C7 0.1uF 5 J8 GND J10 14 12 POWER GOOD J11 C16 0.1uF 13 C12 0.1uF 15 16 U1 SC1109A/B STBY VCC BCAP+ BST DH BCAP- PHASE C4 0.1uF 3 10 R2 0 9 DL VOSENSE GND 7 GATE2 GATE1 LDOS2 LDOS1 8 6 L1 R4 2.2 D1 R3 0 SS/EN PWRGD Q1 IRLR3103 D1N4148 VTT J7 4uH 1.2V 6A Q2 C8 IRLR3103 + C9 + J9 C11 0.1uF C10 + VTT 1500uF 1500uF 1500uF GND J12 2 J13 GND 1 3.3V IN J14 + Q3 IRLR3103 C13 330uF Q4 IRLR3103 1.5V 1.8V J15 + GND + J1 GND J2 5V STBY J3 GND J4 5V IN J5 C2 R1 TBD R5 0 C3 0.1uF + C16 1nF 1500uF C5 11 C6 0.1uF + 1500uF 4 C7 0.1uF 5 J8 GND J10 OCSET GND J19 J18 C1 0.1uF 5V IN J6 GND C15 330uF GND J17 12V IN J16 C14 330uF 14 12 J11 C12 0.1uF 13 15 16 U1 SC1109C STBY VCC BCAP+ BST DH BCAP- PHASE C4 0.1uF 3 10 R2 0 9 R4 2.2 7 D1 SS/EN OCSET DL VOSENSE GATE2 LDOS2 GND GATE1 LDOS1 8 6 R3 0 D1N4148 Q1 IRLR3103 L1 VTT J7 4uH 1.2V 6A Q2 C8 IRLR3103 + C9 + J9 C11 0.1uF C10 + VTT 1500uF 1500uF 1500uF GND J12 2 J13 GND 1 3.3V IN J14 + Q3 IRLR3103 C13 330uF Q4 IRLR3103 1.5V 1.8V J15 GND + C14 330uF GND J17 2004 Semtech Corp. J16 + GND J18 16 C15 330uF J19 www.semtech.com SC1109 POWER MANAGEMENT Evaluation Board Bill of Materials Item Qty. Reference 1 8 C1,C3,C4,C6,C7,C11,C12,C13 0.1F 2 5 C2,C5,C8,C9,C10 1500F 3 3 C13,C14,C15 330F 4 1 C 16 0.1uF(SC1109A/B), 1nF(SC1109C) 5 1 D1 D1N4148 6 1 J1 12V IN 7 9 J2,J4,J8,J10,J12,J13,J17,J18,J19 GND 8 1 J3 5V STBY 9 2 J5,J6 5V IN 10 2 J7,J9 VTT 11 1 J11 POWER GOOD / OCSET 12 1 J1 4 3.3V IN 13 1 J1 5 2.5V 14 1 J1 6 1.8V 15 1 L1 4H 16 4 Q1,Q2,Q3,Q4 IRLR3103 17 1 R1 10k (SC1109A/B), TBD(SC1109C) 18 3 R2,R3,R5 0 19 1 R4 2.2 20 1 U1 SC1109A/B/C 2004 Semtech Corp. Part 17 www.semtech.com SC1109 POWER MANAGEMENT Evaluation Board Gerber Plots Board Layout Assembly Top Board Layout Bottom Board Layout Top 2004 Semtech Corp. 18 www.semtech.com SC1109 POWER MANAGEMENT Outline Drawing - SO-16 Land Pattern - SO-16 Contact Information Semtech Corporation Power Management Products Division 200 Flynn Road, Camarillo, CA 93012 Phone: (805)498-2111 FAX (805)498-3804 2004 Semtech Corp. 19 www.semtech.com