ISL6341BCRZ-T

DATASHEET ISL6341, ISL6341A, ISL6341B, ISL6341C FN6538 Rev 2.00 Dec 2, 2008 5V or 12V Single Synchronous Buck Pulse-Width Modulation (PWM) Controller The ISL6341, ISL6341A, ISL6341B, ISL6341C makes simple work out of implementing a complete control and protection scheme for a DC/DC stepdown converter driving N-Channel MOSFETs in a synchronous buck topology. Since it can work with either 5V or 12V supplies, this one family of IC’s can be used in a wide variety of applications within a system. It integrates the control, gate drivers, output adjustment, monitoring and protection functions into a single 10 Ld Thin DFN package. The ISL6341, ISL6341A, ISL6341B, ISL6341C (hereafter referred to as “ISL6341x”, except as needed) provides single feedback loop, voltage-mode control with fast transient response. The output voltage can be precisely regulated to as low as 0.8V, with a maximum tolerance of ±0.8% over-temperature and line voltage variations. A fixed frequency oscillator and wide duty cycle range reduces design complexity, while balancing typical application cost and efficiency. The frequency, duty cycle and OCP response are the only differences among the ISL6341x versions. See Table 1. Protection from overcurrent conditions is provided by monitoring the rDS(ON) of the lower MOSFET to inhibit PWM operation appropriately (see “Overcurrent Protection (OCP)” on page 8 for details). This approach simplifies the implementation and improves efficiency by eliminating the need for a current sense resistor. The output voltage is also monitored for undervoltage and overvoltage protection, in addition to monitoring for a PGOOD output. Ordering Information PART NUMBER PART TEMP. (Note) MARKING RANGE (°C) PACKAGE (Pb-free) PKG. DWG. # ISL6341ACRZ* 41AC 0 to +70 10 Ld 3x3 TDFN L10.3x3B ISL6341BCRZ* 41BC 0 to +70 10 Ld 3x3 TDFN L10.3x3B ISL6341CCRZ* 41CC 0 to +70 10 Ld 3x3 TDFN L10.3x3B ISL6341CRZ* 341C 0 to +70 10 Ld 3x3 TDFN L10.3x3B ISL6341AIRZ* 41AI -40 to +85 10 Ld 3x3 TDFN L10.3x3B ISL6341BIRZ* 41BI -40 to +85 10 Ld 3x3 TDFN L10.3x3B ISL6341CIRZ* 41CI -40 to +85 10 Ld 3x3 TDFN L10.3x3B ISL6341IRZ* 6341 -40 to +85 10 Ld 3x3 TDFN L10.3x3B ISL6341EVAL1Z Evaluation Board *Add “-T” suffix for tape and reel. Please refer to TB347 for details on reel specifications. NOTE: These Intersil Pb-free plastic packaged products employ special Pb-free material sets, molding compounds/die attach materials, and 100% matte tin plate plus anneal (e3 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations). Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. Features • Operates from +4.5V to 14.4V Supply Voltage (for Bias) - 1.5V to 12V VIN Input Range (Up to 20V is Possible with Restrictions; see “Input Voltage Considerations” on page 12) - 0.8V to ~VIN Output Range (Duty Cycle Limited) - Integrated Gate Drivers; LGATE Uses VCC (5V to 12V); UGATE Uses External Boot Diode to (5V to 12V) - 0.8V Internal Reference; ±0.8% Tolerance • Simple Single-Loop Control Design - Traditional Dual Edge Modulator - Voltage-Mode PWM Control - Drives N-Channel MOSFETs • Fast Transient Response - High-Bandwidth Error Amplifier - 0% to 85% Max Duty Cycle for ISL6341, ISL6341C - 0% to 75% Max Duty Cycle for ISL6341A, ISL6341B • Lossless, Programmable Overcurrent Protection - Uses Lower MOSFET’s rDS(ON) - Latch off mode (ISL6341, ISL6341B) - Infinite Retry (Hiccup) Mode (ISL6341A) - Infinite Retry (Hiccup) Mode; no UVP (ISL6341C) • Output Voltage Monitoring - Undervoltage and Overvoltage Shutdown - PGOOD Output • Small Converter Size in 10 Ld 3x3 Thin DFN - 300kHz Fixed Oscillator (ISL6341, ISL6341C) - 600kHz Fixed Oscillator (ISL6341A, ISL6341B) - Fixed Internal Soft-Start, Capable into a Pre-biased Load - Enable/Shutdown Function on COMP/EN Pin • Pb-Free (RoHS Compliant) Applications • Power Supplies for Microprocessors or Peripherals - PCs, Servers, Memory Supplies - DSP and Core Communications Processor Supplies • Subsystem Power Supplies - PCI, AGP; Graphics Cards; Digital TV - SSTL-2 and DDR/DDR2/DDR3 SDRAM Bus Termination Supply • Cable Modems, Set-Top Boxes, and DSL Modems • Industrial Power Supplies; General Purpose Supplies • 5V or 12V-Input DC/DC Regulators • Low-Voltage Distributed Power Supplies; Point of Load FN6538 Rev 2.00 Dec 2, 2008 Page 1 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C Pinout ISL6341, ISL6341A, ISL6341B, ISL6341C (10 LD 3x3 TDFN) TOP VIEW BOOT 1 10 PGOOD PHASE 2 9 VOS UGATE 3 8 FB LGATE/OCSET 4 7 COMP/EN GND 5 6 VCC Block Diagram VCC + - SAMPLE AND HOLD POR AND SOFT-START OC COMPARATOR INTERNAL REGULATOR BOOT UGATE 5V INT. 10µA TO LGATE/OCSET ERROR AMP 0.8V + - 20k PWM COMPARATOR + - FB INHIBIT GATE CONTROL PWM LOGIC VCC EN + +25% 5V INT. COMP/EN PHASE 20µA 0.7V + -25% + - EN LGATE/OCSET OV1 GND UV1 OSCILLATOR 300kHz OR 600kHz OC + +10% - OV2 PGOOD VOS -10% + - FN6538 Rev 2.00 Dec 2, 2008 UV2 Page 2 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C Typical Application VCC 5V TO 12V VIN 1.5V TO 12V VGD 5V TO 12V CDCPL CHF CBULK VCC BOOT PGOOD 10 1 CBOOT TYPE II COMPENSATION PHASE 2 SHOWN COMP/EN ISL6341x 7 UGATE 3 RF CI FB 8 LGATE/OCSET 4 5 9 CF VOS GND R 6 LOUT +VO COUT OCSET ROFFSET RS RVOS1 RVOS2 FN6538 Rev 2.00 Dec 2, 2008 Page 3 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C Absolute Maximum Ratings Thermal Information Supply Voltage, (VCC) . . . . . . . . . . . . . . . . . . . . GND - 0.3V to 15V BOOT Voltage (VBOOT-GND). . . . . . . . . . . . . . . . GND - 0.3V to 36V BOOT to PHASE Voltage (VBOOT - VPHASE) . . . GND - 0.3V to 15V -0.3V to 16V ( LGATE (12V/DIV) GND> UGATE (24V/DIV) GND> FIGURE 4. OCP TIMING (ISL6341, ISL6341B) Figure 4 shows a typical waveform for the ISL6341, ISL6341B, where the normal inductor current is around 10A, and the OCP trip is 16A. This is just an illustration; the actual shape of the waveforms depends on the component values, as well as the characteristics of the load and the short. On the third trip, the gate drivers stop switching, and the current goes to zero. To recover from this latched off condition, the user must toggle VCC (power-down and power-up) for a new POR, or toggle COMP/EN pin to restart (either includes initialization and soft-start). As the output inductor current rises and falls, the output voltage is also affected. Note that in extreme cases during the three consecutive trips, the UV may actually trip before the OCP. The IC provides protection in either case, but perhaps not quite at the programmed current. An OCP trip can be reset by toggling either POR or COMP/EN, but a UV trip is only reset by toggling POR. See Table 2 for the protection summary. Starting up into a shorted load will be handled the same way; but the waveforms may look different, since the output is not yet at its final value. OCP is always enabled during soft-start (UV is not); it will need the three consecutive trips to latch off. ISL6341A, ISL6341C Figure 5 shows the same conditions for the ISL6341A, ISL6341C. For this version, when overcurrent is first detected (while LGATE is high), the logic will shut off the output (LGATE and UGATE both go low), and the current goes to zero. It will then go into a “hiccup” mode of infinite retries. After two dummy soft-start time-outs, a real soft-start will begin. If the short is still there, it will trip during the soft-start ramp, and will start another retry cycle. Once the short is removed, the next real soft-start will be successful, and normal operation can continue. Page 8 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C . IINDUCTOR (10A/DIV) INTERNAL SOFT-START RAMP DELAYS OC VOUT (0.5V/DIV) 0A> LGATE (12V/DIV) GND> UGATE (24V/DIV) GND> 4.8ms GND> FIGURE 5. OCP TIMING (ISL6341A, ISL6341C) Figure 6 shows the ISL6341A, ISL6341C output response during a retry of an output shorted to GND. At time t0, the output has been turned off, due to sensing an overcurrent condition. There are two internal soft-start delay cycles (t1 and t2) to allow the MOSFETs to cool down, to keep the average power dissipation in retry at an acceptable level. At time t2, the output starts a normal soft-start cycle, and the output tries to ramp. If the short is still applied, and the current reaches the OCSET trip point any time during soft-start ramp period, the output will shut off and return to time t0 for another delay cycle. The retry period is thus two dummy soft-start cycles plus one variable one, which depends on how long it takes to trip the sensor each time. Figure 6 shows an example where the output gets about half-way up before shutting down; therefore, the retry (or hiccup) time will be around 12ms. The minimum should be nominally 9.6ms and the maximum 14.4ms. If the short condition is finally removed, the output should ramp up normally on the next t2 cycle. Starting up into a shorted load looks the same as a retry into that same shorted load. In both cases, OCP is always enabled during soft-start; once it trips, it will go into retry (hiccup) mode. The retry cycle will always have two dummy time-outs, plus whatever fraction of the real soft-start time passes before the detection and shut-off; at that point, the logic immediately starts a new two dummy cycle time-out. Both OCP and UVP protect against shorts to GND, but the responses (and recovery from) are different, as shown in Table 2. For some combinations of output components and shorting method, it may be difficult to predict which protection will trip first (output voltage going too low, or current going too high). The ISL6341C removes that uncertainty by disabling the UVP, and relying only on the OCP. Note that for the other 3 versions, if OCP trips first, it locks out the UVP from also tripping, so that only the OCP response (and recovery) are active. FN6538 Rev 2.00 Dec 2, 2008 t0 4.8ms t1 0ms TO 4.8ms t2 4.8ms t0 FIGURE 6. OCP RETRY OPERATION (ISL6341A, ISL6341C) OVERCURRENT EQUATIONS For all the ISL6341x, versions, the overcurrent function will trip at a peak inductor current (IPEAK) determined by Equation 1: I OCSET xR OCSET I PEAK = ------------------------------------------------r DS  ON  (EQ. 1) where IOCSET is the internal OCSET current source (10µA typical). The OC trip point varies in a system mainly due to the MOSFET’s rDS(ON) variations (over process, current and temperature). To avoid overcurrent tripping in the normal operating load range, find the ROCSET resistor from Equation 1 with: 1. The maximum rDS(ON) at the highest junction temperature. 2. The minimum IOCSET from the “Electrical Specification Table” on page 5.  I  3. Determine IPEAK for I PEAK > I OUT  MAX  + ---------- , 2 whereI is the output inductor ripple current. For an equation for the ripple current see “Output Inductor Selection” on page 15. The range of allowable voltages detected (IOCSET*ROCSET) is 0mV to 550mV; but the practical range for typical MOSFETs is smaller. If the voltage drop across ROCSET is set too low (< ~20mV), that can cause almost continuous OCP tripping. It would also be very sensitive to system noise and in-rush current spikes, so it should be avoided. The maximum setting is 550mV, but most of the recommended MOSFETs for the ISL6341x are not expected to handle the power of the maximum trip point. There is no way to disable the OCP, but setting it above the maximum value (>600mV) will come close; for most cases, it should be high enough (compared to the normal expected range) to appear disabled. No resistor at all could give the clamped maximum value (unless the loading on the LGATE prevents charging the node fully). But there is no low-voltage clamp on LGATE, so it could rise to over 3V and turn-on for 4ms during the sampling; that could discharge a pre-biased Page 9 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C output. Therefore, to avoid that case, but still come close to disabling OCP, a resistor (>60k) is recommended. Note that conditions during power-up may look different than normal operation. For example, during power-up in a 12V system, the IC starts operation just above 4V; if the supply ramp is slow, the soft-start ramp might be over well before 12V is reached. So with lower gate drive voltages, the rDS(ON) of the MOSFETs will be higher during power-up, effectively lowering the OCP trip. In addition, the ripple current will likely be different at lower input voltage. Another factor is the digital nature of the soft-start ramp. On each discrete voltage step, there is in effect a small load transient and a current spike to charge the output capacitors. The height of the current spike is not controlled; it is affected by the step size of the output, the value of the output capacitors, as well as the IC error amp compensation. So it is possible to trip the overcurrent with in-rush current, in addition to the normal load and ripple considerations. OCP is always enabled during soft-start, so there is protection starting up into a shorted load. Undervoltage Protection The output is protected against undervoltage conditions by monitoring the VOS pin. An external resistor divider (similar ratio to the one on the FB pin) makes the voltage equal the 0.8V internal reference under normal operation. If the output goes too low (25% below 0.8V = 0.6V nominal on VOS), the output will latch off, with UGATE and LGATE both forced low. This requires toggling VCC (power-down and up) to restart (toggling COMP/EN will NOT restart it). The UV protection is not enabled until the end of the soft-start ramp (as shown in Figure 2). Figure 7 shows a case where VOUT (and thus VOS) is pulled down to the 75% point; both gate drivers stop switching, and the VOUT is pulled low by the disturbance, as well as the load, at a rate determine by the conditions, and the output components. The ISL6341C version does not have UVP; it relies on the OCP for shorted loads. The PGOOD UV comparator is separate, and is still active. VOUT (0.25V/DIV) 75% GND> LGATE (12V/DIV) GND> UGATE (24V/DIV) GND> FIGURE 7. UNDERVOLTAGE PROTECTION Overvoltage Protection The output is protected against overvoltage conditions by monitoring the VOS pin, similar to undervoltage. If the output goes too high (25% above 0.8V = 1.0V nominal on VOS), the output will latch off. As shown in Figure 8, UGATE will be forced low, but LGATE will be forced high (to try to pull-down the output) until the output drops to 1/2 of the normal voltage (50% of 0.8V = 0.4V nominal on VOS). The LGATE will then shut off, but will keep turning back on whenever the output goes too high again. Overvoltage latch-off requires toggling VCC (power-down and up) to restart (toggling COMP/EN will NOT restart it). The OV protection is not enabled until the rising VCC POR trip point is exceeded. The OV protection is active during soft-start at the fixed 25% above the final expected voltage. The OVP is not gated off by tripping OCP (but the UVP is gated off if OCP trips first). If the VOS pin is disconnected, a small bias current on-chip will force an overvoltage condition. VOUT (0.5V/DIV) 125% 50% GND> LGATE (12V/DIV) GND> UGATE (24V/DIV) GND> FIGURE 8. OVERVOLTAGE PROTECTION FN6538 Rev 2.00 Dec 2, 2008 Page 10 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C PGOOD The PGOOD function output monitors the output voltage using the same VOS pin and resistor divider of the undervoltage and overvoltage protection, but with separate comparators for each. The rising OV trip point (10% above 0.8V = 0.88V nominal on VOS) and the falling UV trip point (10% below 0.8V = 0.72V nominal on VOS) will trip sooner than the protection, in order to give an early warning to a possible problem. The response time of the comparators should be less than 1µs; the separate VOS input is not slowed down by the compensation on the FB pin. It is NOT recommended to connect the VOS pin to the FB pin, in order to share the resistor divider. If the VOS pin is accidentally disconnected, a small bias current on-chip will force an overvoltage condition. Figure 9 shows how the PGOOD output responds to a ramp that trips in each direction (without reaching either protection trip point at ±25%); PGOOD is valid (high) as long as VOUT (and thus VOS) is within the ±10% window. 110% 90% VOUT (0.25V/DIV) PGOOD output should already be low by the time either protection is tripped. TABLE 2. PROTECTION SUMMARY PROTECTION ACTION TAKEN ENABLED AFTER RESET BY OCP ISL6341 ISL6341B VOUT latches off; LGATE and UGATE low. OCP ISL6341A ISL6341C POR or Not Infinite retries; wait ~10ms, and try a new Soft-Start ramp. COMP/EN Applicable ISL6341C has UVP disabled UVP (-25%) VOUT latches off; after SS ramp LGATE and UGATE low. ISL6341C has UVP disabled POR OVP (+25%) POR VOUT latches off; UGATE low; LGATE goes low and high to keep VOUT within 50% and 125% of nominal. VOS pin open will trigger OV. POR PGOOD (UV; -10%) PGOOD goes low if VOS is 10% too low. after SS ramp POR or COMP/EN PGOOD (OV; +10%) PGOOD goes low if VOS is 10% too high. after SS ramp POR or COMP/EN PGOOD (OCP) PGOOD goes low if OCP trips after SS ramp POR or COMP/EN or good SS ramp GND> POR or POR or COMP/EN COMP/EN PGOOD (2V/DIV) Switching Frequency GND> FIGURE 9. PGOOD UNDERVOLTAGE AND OVERVOLTAGE The PGOOD output is an open-drain pull-down NMOS device; it can deliver 4.0mA of sink current at 0.3V when power is NOT GOOD. A pull-up resistor to an external supply voltage sets the high level voltage when power is GOOD. The supply should be 6.0V, and is usually the one that powers the logic monitoring the PGOOD output. If PGOOD function is not used, the PGOOD pin can be left floating. The PGOOD pin will be held low once VCC is above the rising POR trip point, and during soft-start (but if the PGOOD supply is up before or with VCC, it may be pulled high initially until the logic has enough voltage to turn on the output). Once the soft-start ramp is done (VOUT, VOS and FB should each be at 100% of their final value), the PGOOD pin will be allowed to go high, if the output voltage is within the expected window. There is no additional delay after soft-start is done. Note that the overcurrent protection does directly affect the PGOOD output, before the output voltage monitoring would sense when VOUT drops 10%. The overvoltage and undervoltage protection circuits don’t directly effect PGOOD, but since the PGOOD UV and OV windows are tighter, the FN6538 Rev 2.00 Dec 2, 2008 The switching frequency is a fixed 300kHz for the ISL6341, ISL6341C and 600kHz for the ISL6341A, ISL6341B. It cannot be adjusted externally, and the various soft-start delays and ramps are fixed at the same times for either frequency. Output Voltage Selection The output voltage can be programmed to any level between the 0.8V internal reference, up to the VIN supply, with the 85% duty cycle restriction for the ISL6341, ISL6341C (75% for the ISL6341A, ISL6341B). Additional duty cycle margin due to the rDS(ON) drop across the upper FET at maximum load needs to be factored in as well. An external resistor divider is used to scale the output voltage relative to the internal reference voltage, and feed it back to the inverting input of the error amp. See the “Typical Application” schematic on page 3 for more detail; RS is the upper resistor; ROFFSET (shortened to RO below) is the lower one. The recommended value for RS is 1k to 5k (±1% for accuracy) and then ROFFSET is chosen according to Equation 2. Since RS is part of the compensation circuit (see “Feedback Compensation” on page 13), it is often easier to change ROFFSET to change the output voltage; that way the compensation calculations do not need to be repeated. If Page 11 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C VOUT = 0.8V, then ROFFSET can be left open. Output voltages less than 0.8V are not available.  RS + RO  V OUT = 0.8V  --------------------------RO (EQ. 2) R S  0.8V R O = ---------------------------------V OUT – 0.8V The VOS pin is expected to see the same ratio for its resistor divider; RVOS1 should also be chosen in the 1k to 5k (±1% for accuracy) range. To simplify the BOM, RVOS1 should match RS, and RVOS2 should match ROFFSET. If margining (or similar programmability) is added externally (using a switch to change the effective lower resistor value), the same method may be needed on the VOS pin resistor divider. If the new VOUT (FB) is shifted too much compared to the VOS trip, then PGOOD or UV/OV will be more likely to trip in one direction (and less likely in the other). Input Voltage Considerations The “Typical Application” diagram on page 3 shows a standard configuration where VCC is 5V to 12V, which includes the standard 5V (±10%) or 12V (±20%) power supply ranges. The gate drivers use the VCC voltage for LGATE, and VGD (also 5V to 12V) for BOOT/UGATE. There is an internal 5V regulator for bias. The VIN to the upper MOSFET can share the same supply as VCC, but can also run off a separate supply or other sources, such as outputs of other regulators. If VCC powers up first, and the VIN or VGD are not present by the time the initialization is done, then undervoltage will trip at the end of soft-start (and will not recover without toggling VCC; toggling COMP/EN will not restart it). Therefore, either the supplies must be turned on in the proper order (together, or VCC last), or the COMP/EN pin should be used to disable VOUT until all supplies are ready. Figure 10 shows a simple sequencer for this situation. If VCC powers up first, Q1 will be off and R3 pulling to VCC will turn Q2 on, keeping the ISL6341x in shut-down. When VIN turns on, the resistor divider R1 and R2 determines when Q1 turns on, which will turn off Q2, and release the shut-down. VIN R1 R2 R3 TO COMP/EN Q2 FIGURE 10. SEQUENCER CIRCUIT FN6538 Rev 2.00 Dec 2, 2008 The VIN range can be as low as ~1.5V (for VOUT as low as the 0.8V reference). It can be as high as 20V (for VOUT just below VIN, limited by the maximum duty cycle). There are some restrictions for running high VIN voltage. The first consideration for high VIN is the maximum BOOT voltage of 36V. The VIN (as seen on PHASE) plus VGD (boot voltage - minus the diode drop), plus any ringing (or other transients) on the BOOT pin must be less than 36V. If VIN is 20V, that limits VGD plus ringing to 16V. The second consideration is the maximum voltage ratings for VCC and BOOT-PHASE (for VGD); both are set at 15V. If VIN is above the maximum operating range for VCC of 14.4V, then both VCC and VGD need to be supplied separately. They can be derived from VIN (using a linear regulator or equivalent), or they can be independent. In either case, they must satisfy the power supply sequencing requirements noted earlier (either power-up in the proper order, or use a sequencer to disable the output until they are all ready). The third consideration for high VIN is duty cycle. Very low duty cycles (such as 20V in to 1.0V out, for 5% duty cycle) require component selection compatible with that choice (such as low rDS(ON) lower MOSFET, a good LC output filter, and compensation values to match). At the other extreme (for example, 20V in to 12V out), the upper MOSFET needs to be lower rDS(ON). There is also the maximum duty cycle restriction. In all cases, the input and output capacitors and both MOSFETs must be rated for the voltages present. Application Guidelines Layout Considerations VCC Q1 If VIN powers up first, Q1 will be on, turning Q2 off; so the ISL6341x will start-up as soon as VCC comes up. The VENABLE trip point is 0.7V nominal, so a wide variety of NFET’s or NPN’s or even some logic IC’s can be used as Q1 or Q2. But Q2 should pull down hard when on, and must be low leakage when off (open-drain or open-collector) so as not to interfere with the COMP output. The Vth (or Vbe) of Q2 should be reviewed over process and temperature variations to insure that it will work properly under all conditions. Q2 should be placed near the COMP/EN pin. As in any high frequency switching converter, layout is very important. Switching current from one power device to another can generate voltage transients across the impedances of the interconnecting bond wires and circuit traces. These interconnecting impedances should be minimized by using wide, short printed circuit traces. The critical components should be located as close together as possible, using ground plane construction or single point grounding. Page 12 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C address a broad range of applications, a type-3 feedback network is recommended, as shown in the top part of Figure 13. . UGATE Q1 LO PHASE LGATE/OCSET CIN Q2 Figure 13 also highlights the voltage-mode control loop for a synchronous-rectified buck converter, applicable to the ISL6341x circuit. The output voltage (VOUT) is regulated to the reference voltage, VREF. The error amplifier output (COMP pin voltage) is compared with the oscillator (OSC) modified sawtooth wave to provide a pulse-width modulated wave with an amplitude of VIN at the PHASE node. The PWM wave is smoothed by the output filter (L and C). The output filter capacitor bank’s equivalent series resistance is represented by the series resistor E. VOUT LOAD ISL6341x VIN CO RETURN FIGURE 11. PRINTED CIRCUIT BOARD POWER AND GROUND PLANES OR ISLANDS Figure 11 shows the critical power components of the converter. To minimize the voltage overshoot, the interconnecting wires indicated by heavy lines should be part of a ground or power plane in a printed circuit board. The components shown should be located as close together as possible. Please note that the capacitors CIN and CO may each represent numerous physical capacitors. For best results, locate the ISL6341x within 1 inch of the MOSFETs, Q1 and Q2 . The circuit traces for the MOSFET gate and source connections from the ISL6341x must be sized to handle up to 2A peak current. The modulator transfer function is the small-signal transfer function of VOUT /VCOMP. This function is dominated by a DC gain, given by dMAXVIN /VOSC , and shaped by the output filter, with a double pole break frequency at FLC and a zero at FCE . For the purpose of this analysis, L and D represent the channel inductance and its DCR, while C and E represent the total output capacitance and its equivalent series resistance. 1 F LC = --------------------------2  L  C 1 F CE = -----------------------2  C  E C2 +VGD VOS COMP/EN FB ISL6341x +VCC BOOT +VIN CBOOT Q1 LO COMP R2 Q2 CO E/A CVCC GND ROCSET Figure 12 shows the circuit traces that require additional layout consideration. Use single point and ground plane construction for the circuits shown. Provide local VCC decoupling between VCC and GND pins. Locate the capacitor, CBOOT as close as practical to the BOOT and PHASE pins. Locate the resistor, ROSCET close to the LGATE/OCSET pin because the internal current source is only 10µA. Minimize any leakage current paths on the COMP/EN pin. All components used for feedback compensation and VOS resistor divider (inside the dotted box) should be located as close to the IC as practical. Near the load, pick a point VOUT that will be the regulation center; run a single unloaded narrow trace from there to the compensation components. The same trace can also be used for VOS divider. Feedback Compensation This section highlights the design consideration for a voltage-mode controller requiring external compensation. To + R1 FB Ro VREF FIGURE 12. PRINTED CIRCUIT BOARD SMALL SIGNAL LAYOUT GUIDELINES FN6538 Rev 2.00 Dec 2, 2008 C3 R3 C1 PHASE LGATE/OCSET VCC VOUT LOAD VOUT (EQ. 3) VOUT OSCILLATOR VIN PWM CIRCUIT VOSC UGATE HALF-BRIDGE DRIVE L D PHASE C E LGATE ISL6341x EXTERNAL CIRCUIT FIGURE 13. VOLTAGE-MODE BUCK CONVERTER COMPENSATION DESIGN The compensation network consists of the error amplifier (internal to the ISL6341x) and the external R1 to R3, C1 to C3 components. The goal of the compensation network is to provide a closed loop transfer function with high 0dB crossing frequency Page 13 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C (F0; typically 0.1 to 0.3 of fSW) and adequate phase margin (better than 45°). Phase margin is the difference between the closed loop phase at F0dB and 180°. The equations that follow relate the compensation network’s poles, zeros and gain to the components (R1 , R2 , R3 , C1 , C2 , and C3) in Figure 13. Use the following guidelines for locating the poles and zeros of the compensation network: 4. Select a value for R1 (1k to 5k, typically). Calculate the value for R2 for desired converter bandwidth (F0). If setting the output voltage via an offset resistor connected to the FB pin (Ro in Figure 13), the design procedure can be followed as presented in Equation 4. V OSC  R 1  F 0 R 2 = --------------------------------------------d MAX  V IN  F LC (EQ. 4) 5. Calculate C1 such that FZ1 is placed at a fraction of the FLC, at 0.1 to 0.75 of FLC (to adjust, change the 0.5 factor to desired number). The higher the quality factor of the output filter and/or the higher the ratio FCE/FLC, the lower the FZ1 frequency (to maximize phase boost at FLC). 1 C 1 = ----------------------------------------------2  R 2  0.5  F LC R G CL  f  = G MOD  f   G FB  f  where s  f  = 2  f  j (EQ. 8) COMPENSATION BREAK FREQUENCY EQUATIONS 1 F P1 = -------------------------------------------C C R 1 2 2  2  -------------------C C 1+ 2 1 F Z1 = -----------------------------R C 2  2  1 1 F Z2 = -----------------------------------------------R R C 2   1 + 3   3 (EQ. 9) 1 F P2 = -----------------------------R C 2  3  3 FP1 FP2 GAIN FZ1 FZ2 MODULATOR GAIN COMPENSATION GAIN CLOSED LOOP GAIN OPEN LOOP E/A GAIN (EQ. 6) 7. Calculate R3 such that FZ2 is placed at FLC. Calculate C3 such that FP2 is placed below fSW (typically, 0.5 to 1.0 times fSW). fSW represents the switching frequency. Change the numerical factor to reflect desired placement of this pole. Placement of FP2 lower in frequency helps reduce the gain of the compensation network at high frequency, in turn reducing the HF ripple component at the COMP pin and minimizing resultant duty cycle jitter. 1 C 3 = ----------------------------------------------2  R 3  0.7  f SW R  2 20 log  -------- R   1 d MAX  V IN 20 log --------------------------------V OSC 0 GFB GCL LOG C1 C 2 = -------------------------------------------------------2  R 2  C 1  F CE – 1 C 1 + sf  2  1 G FB  f  = ---------------------------------------------------  R C C sf  1   1 + 2 R R C 1 + sf   1 + 3  3  -----------------------------------------------------------------------------------------------------------------------  C1  C2   R C R  1 + s  f   3  3    1 + s  f   2   --------------------    C1 + C2  (EQ. 5) 6. Calculate C2 such that FP1 is placed at FCE. R1 R 3 = -------------------f SW ----------- – 1 F LC d MAX  V IN 1 + sf  E  C G MOD  f  = ------------------------------  ---------------------------------------------------------------------------------------2 V OSC 1 + sf  E + D  C + s f  L  C GMOD LOG FLC FCE F0 FREQUENCY FIGURE 14. ASYMPTOTIC BODE PLOT OF CONVERTER GAIN (EQ. 7) It is recommended that a mathematical model be used to plot the loop response. Check the loop gain against the error amplifier’s open-loop gain. Verify phase margin results and adjust as necessary. Equations 8 and 9 describe the frequency response of the modulator (GMOD), feedback compensation (GFB) and closed-loop response (GCL): Figure 14 shows an asymptotic plot of the DC/DC converter’s gain vs frequency. The actual Modulator Gain has a high gain peak dependent on the quality factor (Q) of the output filter, which is not shown. Using the previous guidelines should yield a compensation gain similar to the curve plotted. The open loop error amplifier gain bounds the compensation gain. Check the compensation gain at FP2 against the capabilities of the error amplifier. The closed loop gain, GCL, is constructed on the log-log graph of Figure 14 by adding the modulator gain, GMOD (in dB), to the feedback compensation gain, GFB (in dB). This is equivalent to multiplying the modulator transfer function and the compensation transfer function and then plotting the resulting gain. A stable control loop has a gain crossing with close to a -20dB/decade slope and a phase margin greater than 45°. Include worst case component variations when determining phase margin. The mathematical model presented makes a number of approximations and is generally not accurate at frequencies approaching or exceeding half the switching FN6538 Rev 2.00 Dec 2, 2008 Page 14 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C frequency. When designing compensation networks, select target crossover frequencies in the range of 10% to 30% of the switching frequency, fSW. This is just one method to calculate compensation components; there are variations of the compensation break frequency equations. The error amp is similar to that on other Intersil regulators, so existing tools can be used here as well. Special consideration is needed if the size of a ceramic output capacitance in parallel with bulk capacitors gets too large; the calculation needs to model them both separately (attempting to combine two different capacitors types into one composite component model may not work properly; a special tool may be needed; contact your local Intersil person for assistance). Component Selection Guidelines Output Capacitor Selection An output capacitor is required to filter the output and supply the load transient current. The filtering requirements are a function of the switching frequency and the ripple current. The load transient requirements are a function of the slew rate (di/dt) and the magnitude of the transient load current. These requirements are generally met with a mix of capacitors and careful layout. Modern components and loads are capable of producing transient load rates above 1A/ns. High frequency capacitors initially supply the transient and slow the current load rate seen by the bulk capacitors. The bulk filter capacitor values are generally determined by the ESR (Effective Series Resistance) and voltage rating requirements rather than actual capacitance requirements. High frequency decoupling capacitors should be placed as close to the power pins of the load as physically possible. Be careful not to add inductance in the circuit board wiring that could cancel the usefulness of these low inductance components. Consult with the manufacturer of the load on specific decoupling requirements. Use only specialized low-ESR capacitors intended for switchingregulator applications for the bulk capacitors. The bulk capacitor’s ESR will determine the output ripple voltage and the initial voltage drop after a high slew-rate transient. An aluminum electrolytic capacitor’s ESR value is related to the case size with lower ESR available in larger case sizes. However, the Equivalent Series Inductance (ESL) of these capacitors increases with case size and can reduce the usefulness of the capacitor to high slew-rate transient loading. Unfortunately, ESL is not a specified parameter. Work with your capacitor supplier and measure the capacitor’s impedance with frequency to select a suitable component. In most cases, multiple electrolytic capacitors of small case size perform better than a single large case capacitor. FN6538 Rev 2.00 Dec 2, 2008 Output Inductor Selection The output inductor is selected to meet the output voltage ripple requirements and minimize the converter’s response time to the load transient. The inductor value determines the converter’s ripple current and the ripple voltage is a function of the ripple current. The ripple voltage and current are approximated by Equation 10: I = VIN - VOUT Fsw x L x VOUT VOUT = I x ESR VIN (EQ. 10) Increasing the value of inductance reduces the ripple current and voltage. However, the large inductance values reduce the converter’s response time to a load transient. One of the parameters limiting the converter’s response to a load transient is the time required to change the inductor current. Given a sufficiently fast control loop design, the ISL6341x will provide either 0% or 100% duty cycle in response to a load transient. The response time is the time required to slew the inductor current from an initial current value to the transient current level. During this interval, the difference between the inductor current and the transient current level must be supplied by the output capacitor. Minimizing the response time can minimize the output capacitance required. The response time to a transient is different for the application of load and the removal of load. Equation 11 gives the approximate response time interval for application and removal of a transient load: tRISE = L x ITRAN VIN - VOUT tFALL = L x ITRAN VOUT (EQ. 11) where: ITRAN is the transient load current step, tRISE is the response time to the application of load, and tFALL is the response time to the removal of load. The worst case response time can be either at the application or removal of load. Be sure to check Equation 11 at the minimum and maximum output levels for the worst case response time. Input Capacitor Selection Use a mix of input bypass capacitors to control the voltage overshoot across the MOSFETs. Use small ceramic capacitors for high frequency decoupling and bulk capacitors to supply the current needed each time Q1 turns on. Place the small ceramic capacitors physically close to the MOSFETs and between the drain of Q1 and the source of Q2 . The important parameters for the bulk input capacitor are the voltage rating and the RMS current rating. For reliable operation, select the bulk capacitor with voltage and current ratings above the maximum input voltage and largest RMS current required by the circuit. The capacitor voltage rating should be at least 1.25x greater than the maximum input voltage and a voltage rating of 1.5x is a conservative guideline. The RMS current rating requirement for the input capacitor of a buck regulator is approximately 1/2 the DC load current. Page 15 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C MOSFET Selection/Considerations The ISL6341x requires 2 N-Channel power MOSFETs. These should be selected based upon rDS(ON) , gate supply requirements, and thermal management requirements. In high-current applications, the MOSFET power dissipation, package selection and heatsink are the dominant design factors. The power dissipation includes two loss components; conduction loss and switching loss. The conduction losses are the largest component of power dissipation for both the upper and the lower MOSFETs. These losses are distributed between the two MOSFETs according to duty factor. The switching losses seen when sourcing current will be different from the switching losses seen when sinking current. When sourcing current, the upper MOSFET realizes most of the switching losses. The lower switch realizes most of the switching losses when the converter is sinking current (see Equation 12). Equation 12 assumes linear voltage-current transitions and does not adequately model power loss due to the reverse-recovery of the upper and lower MOSFET’s body diode. The gate-charge losses are dissipated by the ISL6341x and don't heat the MOSFETs. However, large gatecharge increases the switching interval, tSW which increases the MOSFET switching losses. Ensure that both MOSFETs are within their maximum junction temperature at high ambient temperature by calculating the temperature rise according to package thermal-resistance specifications. A separate heatsink may be necessary depending upon MOSFET power, package type, ambient temperature and air flow. MOSFETs. Look for rDS(ON) ratings at 4.5V. Caution should be exercised with devices exhibiting very low VGS(ON) characteristics. The shoot-through protection present aboard the ISL6341x may be circumvented by these MOSFETs if they have large parasitic impedences and/or capacitances that would inhibit the gate of the MOSFET from being discharged below its threshold level before the complementary MOSFET is turned on. Also avoid MOSFETs with excessive switching times; the circuitry is expecting transitions to occur in under 50ns or so. BOOTSTRAP Considerations Figure 15 shows the upper gate drive (BOOT pin) supplied by a bootstrap circuit from VGD. For convenience, VGD usually shares the VIN or VCC supply; it can be any voltage in the 5V to 12V range. The boot capacitor, CBOOT, develops a floating supply voltage referenced to the PHASE pin. The supply is refreshed to a voltage of VGD less the boot diode drop (VD) each time the lower MOSFET, Q2 , turns on. Check that the voltage rating of the capacitor is above the maximum VCC voltage in the system; a 16V rating should be sufficient for a 12V system. A value of 0.1µF is typical for many systems driving single MOSFETs. If VCC is 12V, but VIN is lower (such as 5V), then another option is to connect the BOOT pin to 12V, and remove the BOOT cap (although, you may want to add a local capacitor from BOOT to GND). This will make the UGATE VGS voltage equal to (12V - 5V = 7V). That should be high enough to drive most MOSFETs, and low enough to improve the efficiency slightly. This also saves a boot diode and capacitor. +VGD +VCC VCC ISL6341x BOOT CBOOT Losses while Sourcing Current 1 P UPPER = Io  r DS  ON   D + ---  Io  V IN  t SW  F S 2 PLOWER = Io2 x rDS(ON) x (1 - D) 2 UGATE Where: D is the duty cycle = VOUT / VIN , tSW is the combined switch ON and OFF time, and fSW is the switching frequency. Q1 PHASE VG-S  VGD - VD VCC Losses while Sinking Current (EQ. 12) PUPPER = Io2 x rDS(ON) x D 2 1 P LOWER = Io  r DS  ON    1 – D  + ---  Io  V IN  t SW  F S 2 +VIN - VD + For a through-hole design, several electrolytic capacitors may be needed. For surface mount designs, solid tantalum capacitors can also be used, but caution must be exercised with regard to the capacitor surge current rating. These capacitors must be capable of handling the surge current at power-up. Some capacitor series available from reputable manufacturers are surge current tested. Q2 - + LGATE/OCSET VG-S  VCC GND FIGURE 15. UPPER GATE DRIVE BOOTSTRAP When operating with a 12V power supply for VCC (or down to a minimum supply voltage of 4.5V), a wide variety of N-MOSFETs can be used. Check the absolute maximum VGS rating for both MOSFETs; it needs to be above the highest VCC voltage allowed in the system; that usually means a 20V VGS rating (which typically correlates with a 30V VDS maximum rating). Low threshold transistors (around 1V or below) are not recommended, as explained in the following. For 5V only operation, given the reduced available gate bias voltage (5V), logic-level transistors should be used for both N- FN6538 Rev 2.00 Dec 2, 2008 Page 16 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C Thin Dual Flat No-Lead Plastic Package (TDFN) L10.3x3B 2X 10 LEAD THIN DUAL FLAT NO-LEAD PLASTIC PACKAGE 0.15 C A A D MILLIMETERS 2X 0.15 C B E SYMBOL MIN NOMINAL MAX NOTES A 0.70 0.75 0.80 - A1 - - 0.05 - A3 6 INDEX AREA b 0.20 REF 0.18 D TOP VIEW D2 B A C SEATING PLANE D2 6 INDEX AREA 0.08 C A3 SIDE VIEW (DATUM B) 0.10 C 7 8 2.23 2.38 2.48 7, 8 1.74 7, 8 3.00 BSC 1.49 e - 1.64 0.50 BSC - k 0.20 - - - L 0.30 0.40 0.50 8 N 10 Nd 5 2 3 2. N is the number of terminals. NX k 3. Nd refers to the number of terminals on D. 4. All dimensions are in millimeters. Angles are in degrees. E2 5. Dimension b applies to the metallized terminal and is measured between 0.15mm and 0.30mm from the terminal tip. E2/2 6. The configuration of the pin #1 identifier is optional, but must be located within the zone indicated. The pin #1 identifier may be either a mold or mark feature. NX L N-1 NX b e (Nd-1)Xe REF. BOTTOM VIEW 5 0.10 M C A B 7. Dimensions D2 and E2 are for the exposed pads which provide improved electrical and thermal performance. 8. Nominal dimensions are provided to assist with PCB Land Pattern Design efforts, see Intersil Technical Brief TB389. 9. COMPLIANT TO JEDEC MO-229-WEED-3 except for dimensions E2 & D2. CL NX (b) - 1. Dimensioning and tolerancing conform to ASME Y14.5-1994. (DATUM A) 8 5, 8 NOTES: 2 N 0.30 Rev. 0 2/06 D2/2 1 E2 0.25 3.00 BSC E // - (A1) 9 L 5 e SECTION "C-C" C C TERMINAL TIP FOR ODD TERMINAL/SIDE FN6538 Rev 2.00 Dec 2, 2008 Page 17 of 18 ISL6341, ISL6341A, ISL6341B, ISL6341C © Copyright Intersil Americas LLC 2007-2008. All Rights Reserved. All trademarks and registered trademarks are the property of their respective owners. For additional products, see www.intersil.com/en/products.html Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted in the quality certifications found at www.intersil.com/en/support/qualandreliability.html Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com FN6538 Rev 2.00 Dec 2, 2008 Page 18 of 18