LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 LM5116WG Wide Range Synchronous Buck Controller Check for Samples: LM5116WG FEATURES DESCRIPTION • The LM5116WG is a synchronous buck controller intended for step-down regulator applications from a high voltage or widely varying input supply. The control method is based upon current mode control utilizing an emulated current ramp. Current mode control provides inherent line feed-forward, cycle by cycle current limiting and ease of loop compensation. The use of an emulated control ramp reduces noise sensitivity of the pulse-width modulation circuit, allowing reliable control of very small duty cycles necessary in high input voltage applications. The operating frequency is programmable from 50 kHz to 1 MHz. The LM5116WG drives external high-side and low-side NMOS power switches with adaptive deadtime control. A user-selectable diode emulation mode enables discontinuous mode operation for improved efficiency at light load conditions. A low quiescent current shutdown disables the controller and consumes less than 10 µA of total input current. Additional features include a high voltage bias regulator, automatic switch-over to external bias for improved efficiency, frequency synchronization, cycle by cycle current limit and adjustable line undervoltage lockout. The device is available in a CPGA-20 high temperature ceramic package with the thermal shutdown feature disabled. 1 2 • • • • • • • • • • • • • • Hermetic Package for Harsh Operating Environments Emulated Peak Current Mode Wide Operating Range up to 100V Low IQ Shutdown (< 10 µA) Drives Standard or Logic Level MOSFETs Robust 3.5A Peak Gate Drive Free-Run or Synchronous Operation to 1 MHz Optional Diode Emulation Mode Programmable Output from 1.215V to 80V Precision 1.5% Voltage Reference Programmable Current Limit Programmable Soft-Start Programmable Line Under-Voltage Lockout Automatic Switch to External Bias Supply CPGA-20 with No Thermal Shutdown Typical Application VIN VIN VCC LM5116WG C VCC RUV2 CIN HB UVLO R UV1 VIN CHB HO EN L VOUT SW C SYNC RT/SYNC C OUT LO RT CS RS CSG COMP C COMP DEMB CHF R COMP VOUT FB SS RAMP C SS AGND C RAMP PGND VCCX R FB2 RFB1 1 2 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. All trademarks are the property of their respective owners. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2008–2013, Texas Instruments Incorporated LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Connection Diagram VIN 1 20 SW UVLO 2 19 HO RT/SYNC 3 18 HB EN 4 17 VCCX RAMP 5 16 VCC AGND 6 15 LO SS 7 14 PGND FB 8 13 CSG COMP 9 12 CS VOUT 10 11 DEMB Figure 1. Top View See Package Number NAR0020A 2 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 PIN DESCRIPTIONS Pin Name Description 1 VIN 2 UVLO Chip supply voltage, input voltage monitor and input to the VCC regulator. 3 RT/SYN C The internal oscillator is set with a single resistor between this pin and the AGND pin. The recommended frequency range is 50 kHz to 1 MHz. The internal oscillator can be synchronized to an external clock by AC coupling a positive edge onto this node. 4 EN If the EN pin is below 0.5V, the regulator will be in a low power state drawing less than 10 µA from VIN. EN must be pulled above 3.3V for normal operation. 5 RAMP Ramp control signal. An external capacitor connected between this pin and the AGND pin sets the ramp slope used for current mode control. 6 AGND Analog ground. Connect directly to PGND under the LM5116WG. 7 SS An external capacitor and an internal 10 µA current source set the soft start time constant for the rise of the error amp reference. The SS pin is held low during VCC < 4.5V, UVLO < 1.215V, or EN input low. 8 FB Feedback signal from the regulated output. This pin is connected to the inverting input of the internal error amplifier. The regulation threshold is 1.215V. 9 COMP Output of the internal error amplifier. The loop compensation network should be connected between this pin and the FB pin. 10 VOUT Output monitor. Connect directly to the output voltage. 11 DEMB Low-side MOSFET source voltage monitor for diode emulation. For start-up into a pre-biased load, tie this pin to ground at the CSG connection. For fully synchronous operation, use an external series resistor between DEMB and ground to raise the diode emulation threshold above the low-side SW on-voltage. 12 CS 13 CSG 14 PGND 15 LO If the UVLO pin is below 1.215V, the regulator will be in standby mode (VCC regulator running, switching regulator disabled). If the UVLO pin voltage is above 1.215V, the regulator is operational. An external voltage divider can be used to set an under-voltage shutdown threshold. There is a fixed 5 µA pull up current on this pin when EN is high. UVLO is pulled to ground in the event a current limit condition exists for 256 clock cycles. Current sense amplifier input. Connect to the top of the current sense resistor or the drain of the low-sided MOSFET if RDS(ON) current sensing is used. Current sense amplifier input. Connect to the bottom of the sense resistor or the source of the low-side MOSFET if RDS(ON) current sensing is used. Power ground. Connect directly to AGND under the LM5116WG. Connect to the gate of the low-side synchronous MOSFET through a short, low inductance path. 16 VCC 17 VCCX Locally decouple to PGND using a low ESR/ESL capacitor located as close to the controller as possible. 18 HB High-side driver supply for bootstrap gate drive. Connect to the cathode of the bootstrap diode and the positive terminal of the bootstrap capacitor. The bootstrap capacitor supplies current to charge the high-side MOSFET gate and should be placed as close to the controller as possible. 19 HO Connect to the gate of the high-side synchronous MOSFET through a short, low inductance path. 20 SW Switch node. Connect to the negative terminal of the bootstrap capacitor and the source terminal of the high-side MOSFET. Optional input for an externally supplied VCC. If VCCX > 4.5V, VCCX is internally connected to VCC and the internal VCC regulator is disabled. If VCCX is unused, it should be connected to ground. These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 3 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Absolute Maximum Ratings (1) (2) VIN to GND -0.3V to 100V VCC, VCCX, UVLO to GND (3) -0.3 to 16V SW, CS to GND -3.0 to 100V HB to SW -0.3 to 16V HO to SW -0.3 to HB+0.3V VOUT to GND -0.3 to 100V CSG to GND -1V to 1V LO to GND -0.3 to VCC+0.3V SS to GND -0.3 to 7V FB to GND -0.3 to 7V DEMB to GND -0.3 to VCC RT to GND -0.3 to 7V EN to GND -0.3 to 100V ESD Rating HBM (4) 2 kV Storage Temperature Range -55°C to +150°C Junction Temperature (1) (2) (3) (4) +150°C Absolute Maximum Ratings indicate limits beyond which damage to the component may occur. If Military/Aerospace specified devices are required, please contact the TI Sales Office/Distributors for availability and specifications. These pins must not exceed VIN. The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin. LO, HO and HB are rated at 1 kV. 2 kV rating for all pins except VIN which is rated for 1.5 kV. Operating Ratings (1) (2) VIN 6V to 100V VCC, VCCX 4.75V to 15V HB to SW 4.75V to 15V DEMB to GND -0.3V to 2V Junction Temperature (1) (2) -40°C to +125°C Operating Ratings are conditions under which operation of the device is intended to be functional. Operating Ratings do not imply guaranteed performance limits. Note: RAMP, COMP are output pins. As such they are not specified to have an external voltage applied. Electrical Characteristics Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature range of -40°C to +125°C and are provided for reference only. Unless otherwise specified, the following conditions apply: VIN = 48V, VCC = 7.4V, VCCX = 0V, EN = 5V, RT = 16 kΩ, no load on LO and HO. Symbol Parameter Conditions VIN Operating Current Min Typ Max Units VCCX = 0V, VIN = 48V 5 7 mA VCCX = 0V, VIN = 100V 5.9 8 mA VCCX = 5V, VIN = 48V 1.2 1.7 mA VCCX = 5V, VIN = 100V 1.6 2.3 mA EN = 0V, VIN = 48V 1 10 µA EN = 0V, VIN = 100V 1 VIN Supply IBIAS IBIASX ISTDBY 4 VIN Operating Current VIN Shutdown Current Submit Documentation Feedback µA Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Electrical Characteristics (continued) Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature range of -40°C to +125°C and are provided for reference only. Unless otherwise specified, the following conditions apply: VIN = 48V, VCC = 7.4V, VCCX = 0V, EN = 5V, RT = 16 kΩ, no load on LO and HO. Symbol Parameter Conditions Min Typ Max Units 7.1 7.4 7.7 V VCC Regulator VCC(REG) VCC Regulation VCC LDO Mode Turn-off 10.6 VCC Regulation VIN = 6V 5.0 5.9 VCC Sourcing Current Limit VCC = 0V 15 26 VCCX Switch Threshold VCCX Rising 4.3 VCCX Switch Hysteresis 4.5 V 6.0 4.7 V 6.2 Ω 0.25 VCCX Switch RDS(ON) ICCX = 10 mA VCCX Leakage VCCX = 0V VCCX Pull- down Resistance VCCX = 3V VCC Under-voltage Threshold VCC Rising 3.8 nA 100 VCC Under-voltage Hysteresis HB DC Bias Current V -200 4.3 4.5 kΩ 4.7 0.2 HB - SW = 15V 125 V mA V V 200 µA 0.5 V 1 µA EN Input VIL max EN Input Low Threshold VIH min EN Input High Threshold 3.3 EN Input Bias Current VEN = 3V EN Input Bias Current VEN = 0.5V EN Input Bias Current VEN = 100V UVLO Standby Threshold UVLO Rising -7.5 -1 V -3 0 1 µA 20 90 µA 1.215 1.262 V UVLO Thresholds 1.170 UVLO Threshold Hysteresis UVLO Pull-up Current Source 0.1 UVLO = 0V V 5.4 UVLO Pull-down RDS(ON) µA 80 210 Ω 11 14 µA Soft Start SS Current Source SS = 0V SS Diode Emulation Ramp Disable Threshold SS Rising SS to FB Offset 8 3 V FB = 1.25V 160 mV SS Output Low Voltage Sinking 100 µA, UVLO = 0V 45 mV FB Reference Voltage Measured at FB pin, FB = COMP FB Input Bias Current FB = 2V Error Amplifier VREF COMP Sink/Source Current 1.195 1.215 1.231 15 500 3 V nA mA AOL DC Gain 80 dB fBW Unity Gain Bandwidth 3 MHz PWM Comparators tHO(OFF) Forced HO Off-time 320 tON(min) Minimum HO On-time VIN = 80V, CRAMP = 50 pF fSW1 Frequency 1 RT = 16 kΩ fSW2 Frequency 2 RT = 5 kΩ 450 580 100 ns ns Oscillator RT output voltage RT sync positive threshold 180 200 220 kHz 480 535 590 kHz 1.191 1.215 1.239 V 3.0 3.5 4.0 V Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 5 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Electrical Characteristics (continued) Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature range of -40°C to +125°C and are provided for reference only. Unless otherwise specified, the following conditions apply: VIN = 48V, VCC = 7.4V, VCCX = 0V, EN = 5V, RT = 16 kΩ, no load on LO and HO. Symbol Parameter Conditions Min Typ Max Units Current Limit VCS(TH) Cycle-by-cycle Sense Voltage Threshold VCCX = 0V, RAMP = 0V (CSG - CS) 94 110 126 mV VCS(THX) Cycle-by-cycle Sense Voltage Threshold VCCX = 5V, RAMP = 0V (CSG - CS) 105 122 139 mV 1 µA µA CS Bias Current CS = 100V -1 CS Bias Current CS = 0V 90 125 CSG Bias Current CSG = 0V 90 125 Current Limit Fault Timer RT = 16 kΩ, (200 kHz), (256 clock cycles) IR1 RAMP Current 1 VIN = 60V, VOUT=10V 235 285 335 µA IR2 RAMP Current 2 VIN = 10V, VOUT = 10V 21 28 35 µA VOUT Bias Current VOUT = 36V 200 µA RAMP Output Low Voltage VIN = 60V, VOUT = 10V 265 mV 1.28 µA ms RAMP Generator Diode Emulation SW Zero Cross Threshold -6 mV DEMB Output Current DEMB = 0V, SS = 1.25V 1.6 2.7 3.8 µA DEMB Output Current DEMB =0V, SS = 2.8V 28 38 48 µA DEMB Output Current DEMB = 0V, SS = Regulated by FB 45 65 85 µA VOLL LO Low-state Output Voltage ILO = 100 mA 0.08 0.17 V VOHL LO High-state Output Voltage ILO = -100 mA, VOHL = VCC VLO 0.25 V LO Rise Time C-load = 1000 pF 18 ns LO Gate Driver LO Fall Time C-load = 1000 pF 12 ns IOHL Peak LO Source Current VLO = 0V 1.8 A IOLL Peak LO Sink Current VLO = VCC 3.5 A VOLH HO Low-state Output Voltage IHO = 100 mA 0.17 VOHH HO High-state Output Voltage IHO = -100 mA, VOHH = VHB VHO 0.45 V HO Rise Time C-load = 1000 pF 19 ns HO High-side Fall Time C-load = 1000 pF 13 ns IOHH Peak HO Source Current VHO = 0V 1 A IOLH Peak HO Sink Current VHO = VCC 2.2 A 3 V HO Gate Driver HB to SW under-voltage 0.27 V Switching Characteristics LO Fall to HO Rise Delay C-load = 0 75 ns HO Fall to LO Rise Delay C-load = 0 70 ns Thermal 6 θJA Junction to Ambient 115 °C/W θJC Junction to Case 13 °C/W Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Typical Performance Characteristics FB Reference Voltage vs Temperature FB Input Bias Current vs Temperature Figure 2. Figure 3. EN Input Threshold vs Temperature VIN Operating Current vs Temperature Figure 4. Figure 5. SS Current vs Temperature RAMP Current vs Temperature Figure 6. Figure 7. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 7 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Typical Performance Characteristics (continued) 8 VCC UVLO vs Temperature VCC LDO Switch vs Temperature Figure 8. Figure 9. VCC Regulation vs Temperature VCC Current Limit vs Temperature Figure 10. Figure 11. VCCX Switch Threshold vs Temperature VCCX Switch RDS(ON) vs Temperature Figure 12. Figure 13. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Typical Performance Characteristics (continued) Frequency vs Temperature Frequency vs Temperature Figure 14. Figure 15. RT/SYNC Threshold vs Temperature RT/SYNC Hysteresis vs Temperature Figure 16. Figure 17. Forced HO Off-Time vs Temperature DEMB Output Current vs Temperature Figure 18. Figure 19. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 9 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Typical Performance Characteristics (continued) 10 Current Limit Threshold vs Temperature HO UVLO vs Temperature Figure 20. Figure 21. CS & CSG Input Bias Current vs Temperature HO & LO Delay vs Temperature Figure 22. Figure 23. CS Input Bias Current vs Temperature HB Input Bias Current vs Temperature Figure 24. Figure 25. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Block Diagram and Typical Application Circuit VCCX 17 VCCX LM5116WG VIN 6V-100V C IN 1 VIN R UV2 VCC 16 UVLO SLEEP MODE SHUTDOWN 1.215V STANDBY D2 HB 18 5 PA UVLO LOGIC C FT HICCUP FAULT TIMER 256 CLOCK CYCLES UVLO DIS CHB VIN DRIVER HO 19 CLK 7 SS 10 PA 3V PWM CSS C COMP R Q ADAPTIVE TIMER TRACK SAMPLE and HOLD 1.6V COMP + 3 L1 10 x RS V/A LO 15 A =10 Q2 CSNUB COUT R SNUB RS 0.5V CSG 13 SW DIODE EMULATION CONTROL VIN OSCILLATOR DEMB 11 VOUT 10 R FB2 RAMP GENERATOR I R = 5 PA / V x ( VIN - VOUT ) + 25 PA RT VOUT 20 CLK CLK RT/SYNC Q1 CS 12 SS C SYNC SW VCC DRIVER R COMP 9 Q CURRENT LIMIT ERROR AMP CHF S 1V 1.215 V 8 FB SYNC C VCC D1 4 EN 2 UVLO R UV1 + - 7. 4 V REGULATOR R EN EN 4.5V C VCCX IR R FB1 RAMP AGND 5 6 PGND 14 CRAMP Figure 26. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 11 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com DETAILED OPERATING DESCRIPTION The LM5116WG high voltage switching regulator features all of the functions necessary to implement an efficient high voltage buck regulator using a minimum of external components. This easy to use regulator integrates highside and low-side MOSFET drivers capable of supplying peak currents of 2 Amps. The regulator control method is based on current mode control utilizing an emulated current ramp. Emulated peak current mode control provides inherent line feed-forward, cycle by cycle current limiting and ease of loop compensation. The use of an emulated control ramp reduces noise sensitivity of the pulse-width modulation circuit, allowing reliable processing of the very small duty cycles necessary in high input voltage applications. The operating frequency is user programmable from 50 kHz to 1 MHz. An oscillator/synchronization pin allows the operating frequency to be set by a single resistor or synchronized to an external clock. Fault protection features include current limiting and remote shutdown capability. An under-voltage lockout input allows regulator shutdown when the input voltage is below a user selected threshold, and an enable function will put the regulator into an extremely low current shutdown via the enable input. High Voltage Start-Up Regulator The LM5116WG contains a dual mode internal high voltage startup regulator that provides the VCC bias supply for the PWM controller and a boot-strap gate drive for the high-side buck MOSFET. The input pin (VIN) can be connected directly to an input voltage source as high as 100 volts. For input voltages below 10.6V, a low dropout switch connects VCC directly to VIN. In this supply range, VCC is approximately equal to VIN. For VIN voltages greater than 10.6V, the low dropout switch is disabled and the VCC regulator is enabled to maintain VCC at approximately 7.4V. The wide operating range of 6V to 100V is achieved through the use of this dual mode regulator. Upon power-up, the regulator sources current into the capacitor connected to the VCC pin. When the voltage at the VCC pin exceeds 4.5V and the UVLO pin is greater than 1.215V, the output switch is enabled and a soft-start sequence begins. The output switch remains enabled until VCC falls below 4.5V, EN is pulled low or the UVLO pin falls below 1.215V. VCCX CVCCX VOUT SW L COUT Figure 27. VCCX Bias Supply with Additional Inductor Winding An output voltage derived bias supply can be applied to the VCCX pin to reduce the IC power dissipation. If the bias supply voltage is greater than 4.5V, the internal regulator will essentially shut off, reducing the IC power dissipation. The VCC regulator series pass transistor includes a diode between VCC and VIN that should not be forward biased in normal operation. For an output voltage between 5V and 15V, VOUT can be connected directly to VCCX. For VOUT < 5V, a bias winding on the output inductor can be added to VOUT. If the bias winding can supply VCCX greater than VIN, an external blocking diode is required from the input power supply to the VIN pin to prevent VCC from discharging into the input supply. The output of the VCC regulator is current limited to 15 mA minimum. The VCC current is determined by the MOSFET gate charge, switching frequency and quiescent current (see MOSFETs section in the Application Information). If VCCX is powered by the output voltage or an inductor winding, the VCC current should be evaluated during startup to ensure that it is less than the 15 mA minimum current limit specification. IF VCCX is powered by an external regulator derived from VIN, there is no restriction on the VCC current. 12 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 VIN 1 VIN 0.1 PF 6 AGND Figure 28. Input Blocking Diode for VCCX > VIN In high voltage applications extra care should be taken to ensure the VIN pin does not exceed the absolute maximum voltage rating of 100V. During line or load transients, voltage ringing on the VIN line that exceeds the Absolute Maximum Ratings can damage the IC. Both careful PC board layout and the use of quality bypass capacitors located close to the VIN and GND pins are essential. Enable The LM5116WG contains an enable function allowing a very low input current shutdown. If the enable pin is pulled below 0.5V, the regulator enters shutdown, drawing less than 10 µA from the VIN pin. Raising the EN input above 3.3V returns the regulator to normal operation. The maximum EN transition time for proper operation is one switching period. For example, the enable rise time must be less than 4 μs for 250 kHz operation. A 1 MΩ pull-up resistor to VIN can be used to interface with an open collector control signal. At low input voltage the pull-up resistor may be reduced to 100 kΩ to speed up the EN transition time. The EN pin can be tied directly to VIN if this function is not needed. It must not be left floating. If low-power shutdown is not needed, the UVLO pin should be used as an on/off control. Internal 5V rail 3 PA EN 6V Figure 29. Enable Circuit Figure 30. EN Bias Current vs Voltage Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 13 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com UVLO An under-voltage lockout pin is provided to disable the regulator without entering shutdown. If the UVLO pin is pulled below 1.215V, the regulator enters a standby mode of operation with the soft-start capacitor discharged and outputs disabled, but with the VCC regulator running. If the UVLO input is pulled above 1.215V, the controller will resume normal operation. A voltage divider from input to ground can be used to set a VIN threshold to disable the supply in brown-out conditions or for low input faults. The UVLO pin has a 5 µA internal pull up current that allows this pin to left open if the input under-voltage lockout function is not needed. For applications which require fast on/off cycling, the UVLO pin with an open collector control signal may be used to ensure proper start-up sequencing. The UVLO pin is also used to implement a “hiccup” current limit. If a current limit fault exists for more than 256 consecutive clock cycles, the UVLO pin will be internally pulled down to 200 mV and then released. A capacitor to ground connected to the UVLO pin will set the timing for hiccup mode current limit. When this feature is used in conjunction with the voltage divider, a diode across the top resistor may be used to discharge the capacitor in the event of an input under-voltage condition. There is a 5 µs filter at the input to the fault comparator. At higher switching frequency (greater than approximately 250 kHz) the hiccup timer may be disabled if the fault capacitor is not used. Oscillator and Sync Capability The LM5116WG oscillator frequency is set by a single external resistor connected between the RT/SYNC pin and the AGND pin. The resistor should be located very close to the device and connected directly to the pins of the IC (RT/SYNC and AGND). To set a desired oscillator frequency (fSW), the necessary value for the resistor can be calculated from the following equation: RT = T - 450 ns 284 pF (1) Where T = 1 / fSW and RT is in ohms. 450 ns represents the fixed minimum off time. The LM5116WG oscillator has a maximum programmable frequency that is dependent on the VCC voltage. If VCC is above 6V, the frequency can be programmed up to 1 MHz. If VCCX is used to bias VCC and VCCX < 6V, the maximum programmable oscillator frequency is 750 kHz. The RT/SYNC pin can be used to synchronize the internal oscillator to an external clock. The external clock must be a higher frequency than the free-running frequency set by the RT resistor. The internal oscillator can be synchronized to an external clock by AC coupling a positive edge into the RT/SYNC pin. The voltage at the RT/SYNC pin is nominally 1.215V and must exceed 4V to trip the internal synchronization pulse detection. A 5V amplitude signal and 100 pF coupling capacitor are recommended. The free-running frequency should be set nominally 15% below the external clock. Synchronizing above twice the free-running frequency may result in abnormal behavior of the pulse width modulator. Error Amplifier and PWM Comparator The internal high-gain error amplifier generates an error signal proportional to the difference between the regulated output voltage and an internal precision reference (1.215V). The output of the error amplifier is connected to the COMP pin allowing the user to provide loop compensation components, generally a type II network. This network creates a pole at very low frequency, a mid-band zero, and a noise reducing high frequency pole. The PWM comparator compares the emulated current sense signal from the RAMP generator to the error amplifier output voltage at the COMP pin. Ramp Generator The ramp signal used in the pulse width modulator for current mode control is typically derived directly from the buck switch current. This switch current corresponds to the positive slope portion of the inductor current. Using this signal for the PWM ramp simplifies the control loop transfer function to a single pole response and provides inherent input voltage feed-forward compensation. The disadvantage of using the buck switch current signal for PWM control is the large leading edge spike due to circuit parasitics that must be filtered or blanked. Also, the current measurement may introduce significant propagation delays. The filtering, blanking time and propagation delay limit the minimal achievable pulse width. In applications where the input voltage may be relatively large in 14 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 comparison to the output voltage, controlling small pulse widths and duty cycles is necessary for regulation. The LM5116WG utilizes a unique ramp generator which does not actually measure the buck switch current but rather reconstructs the signal. Representing or emulating the inductor current provides a ramp signal to the PWM comparator that is free of leading edge spikes and measurement or filtering delays. The current reconstruction is comprised of two elements, a sample-and-hold DC level and an emulated current ramp. (5 PA/V x (VIN-VOUT) + 25 PA) x tON CRAMP RAMP Sample and Hold DC Level 10 x RS V/A tON Figure 31. Composition of Current Sense Signal The sample-and-hold DC level is derived from a measurement of the recirculating current through either the lowside MOSFET or current sense resistor. The voltage level across the MOSFET or sense resistor is sampled and held just prior to the onset of the next conduction interval of the buck switch. The current sensing and sampleand-hold provide the DC level of the reconstructed current signal. The positive slope inductor current ramp is emulated by an external capacitor connected from the RAMP pin to the AGND and an internal voltage controlled current source. The ramp current source that emulates the inductor current is a function of the VIN and VOUT voltages per the following equation: IR = 5 µA/V x (VIN - VOUT) + 25 µA (2) Proper selection of the RAMP capacitor (CRAMP) depends upon the value of the output inductor (L) and the current sense resistor (RS). For proper current emulation, the DC sample and hold value and the ramp amplitude must have the same dependence on the load current. That is: RS x A = CRAMP = gm x L , so CRAMP gm x L A x RS (3) Where gm is the ramp generator transconductance (5 µA/V) and A is the current sense amplifier gain (10 V/V). The ramp capacitor should be located very close to the device and connected directly to the pins of the IC (RAMP and AGND). The difference between the average inductor current and the DC value of the sampled inductor current can cause instability for certain operating conditions. This instability is known as sub-harmonic oscillation, which occurs when the inductor ripple current does not return to its initial value by the start of next switching cycle. Sub-harmonic oscillation is normally characterized by observing alternating wide and narrow pulses at the switch node. Adding a fixed slope voltage ramp (slope compensation) to the current sense signal prevents this oscillation. The 25 µA of offset current provided from the emulated current source adds the optimal slope compensation to the ramp signal for a 5V output. For higher output voltages, additional slope compensation may be required. In these applications, a resistor is added between RAMP and VCC to increase the ramp slope compensation. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 15 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com SW LO RG CS RG CSG DEMB RDEMB Figure 32. RDS(ON) Current Sensing without Diode Emulation The DC current sample is obtained using the CS and CSG pins connected to either a source sense resistor (RS) or the RDS(ON) of the low-side MOSFET. For RDS(ON) sensing, RS = RDS(ON) of the low-side MOSFET. In this case it is sometimes helpful to adjust the current sense amplifier gain (A) to a lower value in order to obtain the desired current limit. Adding external resistors RG in series with CS and CSG, the current sense amplifier gain A becomes: A, 10k 1k + RG (4) Current Limit The LM5116WG contains a current limit monitoring scheme to protect the circuit from possible over-current conditions. When set correctly, the emulated current sense signal is proportional to the buck switch current with a scale factor determined by the current limit sense resistor. The emulated ramp signal is applied to the current limit comparator. If the emulated ramp signal exceeds 1.6V, the current cycle is terminated (cycle-by-cycle current limiting). Since the ramp amplitude is proportional to VIN - VOUT, if VOUT is shorted, there is an immediate reduction in duty cycle. To further protect the external switches during prolonged current limit conditions, an internal counter counts clock pulses when in current limit. When the counter detects 256 consecutive clock cycles, the regulator enters a low power dissipation hiccup mode of current limit. The regulator is shut down by momentarily pulling UVLO low, and the soft-start capacitor discharged. The regulator is restarted with a full softstart cycle once UVLO charges back to 1.215V. This process is repeated until the fault is removed. The hiccup off-time can be controlled by a capacitor to ground on the UVLO pin. In applications with low output inductance and high input voltage, the switch current may overshoot due to the propagation delay of the current limit comparator. If an overshoot should occur, the sample-and-hold circuit will detect the excess recirculating current. If the sample-and-hold DC level exceeds the internal current limit threshold, the buck switch will be disabled and skip pulses until the current has decayed below the current limit threshold. This approach prevents current runaway conditions due to propagation delays or inductor saturation since the inductor current is forced to decay following any current overshoot. CURRENT SENSE CURRENT LIMIT COMPARATOR AMPLIFIER 1.6V - 10k LO 1k CS RG 1k CSG RG + -RS ++ gm x (VIN - VOUT) + 25 PA 10k IL 0.5V HO RAMP A= 10k 1k + RG CRAMP Figure 33. Current Limit and Ramp Circuit 16 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Using a current sense resistor in the source of the low-side MOSFET provides superior current limit accuracy compared to RDS(ON) sensing. RDS(ON) sensing is far less accurate due to the large variation of MOSFET RDS(ON) with temperature and part-to-part variation. The CS and CSG pins should be Kelvin connected to the current sense resistor or MOSFET drain and source. The peak current which triggers the current limit comparator is: 1.1V IPEAK = 25 PA x tON CRAMP A x RS , 1.1V A x RS (5) Where tON is the on-time of the high-side MOSFET. The 1.1V threshold is the difference between the 1.6V reference at the current limit comparator and the 0.5V offset at the current sense amplifier. This offset at the current sense amplifier allows the inductor ripple current to go negative by 0.5V / (A x RS) when running full synchronous operation. Current limit hysteresis prevents chatter around the threshold when VCCX is powered from VOUT. When 4.5V < VCC < 5.8V, the 1.6V reference is increased to 1.72V. The peak current which triggers the current limit comparator becomes: 1.22V IPEAK = 25 PA x tON CRAMP A x RS , 1.22V A x RS (6) This has the effect of a 10% fold-back of the peak current during a short circuit when VCCX is powered from a 5V output. Soft-Start and Diode Emulation The soft-start feature allows the regulator to gradually reach the initial steady state operating point, thus reducing start-up stresses and surges. The LM5116WG will regulate the FB pin to the SS pin voltage or the internal 1.215V reference, whichever is lower. At the beginning of the soft-start sequence when SS = 0V, the internal 10 µA soft-start current source gradually increases the voltage of an external soft-start capacitor (CSS) connected to the SS pin resulting in a gradual rise of FB and the output voltage. DIODE EMULATION COMPARATOR + RS RDEMB SW DEMB 1.215V 5V 40k SS Latch + SS - Figure 34. Diode Emulation Control During this initial charging of CSS to the internal reference voltage, the LM5116WG will force diode emulation. That is, the low-side MOSFET will turn off for the remainder of a cycle if the sensed inductor current becomes negative. The inductor current is sensed by monitoring the voltage between SW and DEMB. As the SS capacitor continues to charge beyond 1.215V to 3V, the DEMB bias current will increase from 0 µA up to 40 µA. With the use of an external DEMB resistor (RDEMB), the current sense threshold for diode emulation will increase resulting in the gradual transition to synchronous operation. Forcing diode emulation during soft-start allows the LM5116WG to start up into a pre-biased output without unnecessarily discharging the output capacitor. Full synchronous operation is obtained if the DEMB pin is always biased to a higher potential than the SW pin when LO is high. RDEMB = 10 kΩ will bias the DEMB pin to 0.45V minimum, which is adequate for most applications. The DEMB bias potential should always be kept below 2V. At very light loads with larger values of output inductance and MOSFET capacitance, the switch voltage may fall slowly. If the SW voltage does not fall below the DEMB threshold before the end of the HO fall to LO rise dead-time, switching will default to diode emulation mode. When RDEMB = 0Ω, the LM5116WG will always run in diode emulation. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 17 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Once SS charges to 3V the SS latch is set, increasing the DEMB bias current to 65 µA. An amplifier is enabled that regulates SS to 160 mV above the FB voltage. This feature can prevent overshoot of the output voltage in the event the output voltage momentarily dips out of regulation. When a fault is detected (VCC under-voltage, UVLO pin < 1.215, or EN = 0V) the soft-start capacitor is discharged. Once the fault condition is no longer present, a new soft-start sequence begins. HO Ouput The LM5116WG contains a high current, high-side driver and associated high voltage level shift. This gate driver circuit works in conjunction with an external diode and bootstrap capacitor. A 1 µF ceramic capacitor, connected with short traces between the HB pin and SW pin, is recommended. During the off-time of the high-side MOSFET, the SW pin voltage is approximately -0.5V and the bootstrap capacitor charges from VCC through the external bootstrap diode. When operating with a high PWM duty cycle, the buck switch will be forced off each cycle for 450 ns to ensure that the bootstrap capacitor is recharged. The LO and HO outputs are controlled with an adaptive deadtime methodology which insures that both outputs are never enabled at the same time. When the controller commands HO to be enabled, the adaptive block first disables LO and waits for the LO voltage to drop below approximately 25% of VCC. HO is then enabled after a small delay. Similarly, when HO turns off, LO waits until the SW voltage has fallen to ½ of VCC. LO is then enabled after a small delay. In the event that SW does not fall within approximately 150 ns, LO is asserted high. This methodology insures adequate dead-time for appropriately sized MOSFETs. In some applications it may be desirable to slow down the high-side MOSFET turn-on time in order to control switching spikes. This may be accomplished by adding a resistor is series with the HO output to the high-side gate. Values greater than 10Ω should be avoided so as not to interfere with the adaptive gate drive. Use of an HB resistor for this function should be carefully evaluated so as not cause potentially harmful negative voltage to the high-side driver, and is generally limited to 2.2Ω maximum. Thermal Protection For high temperature applications in the CPGA-20, the internal thermal shutdown circuitry is disabled. Application Information EXTERNAL COMPONENTS The procedure for calculating the external components is illustrated with the following design example. The Bill of Materials for this design is listed in Table 1. The circuit shown in Figure 41 is configured for the following specifications: • Output voltage = 5V • Input voltage = 7V to 60V • Maximum load current = 7A • Switching frequency = 250 kHz Simplified equations are used as a general guideline for the design method. Comprehensive equations are provided at the end of this section. TIMING RESISTOR RT sets the oscillator switching frequency. Generally, higher frequency applications are smaller but have higher losses. Operation at 250 kHz was selected for this example as a reasonable compromise for both small size and high efficiency. The value of RT for 250 kHz switching frequency can be calculated as follows: 1 - 450 ns 250 kHz = 12.5 k: RT = 284 pF (7) The nearest standard value of 12.4 kΩ was chosen for RT. 18 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 OUTPUT INDUCTOR The inductor value is determined based on the operating frequency, load current, ripple current and the input and output voltages. IPP IO 0 T= 1 fSW Figure 35. Inductor Current Knowing the switching frequency (fSW), maximum ripple current (IPP), maximum input voltage (VIN(MAX)) and the nominal output voltage (VOUT), the inductor value can be calculated: L= VOUT IPP x fSW x 1- VOUT VIN(MAX) (8) The maximum ripple current occurs at the maximum input voltage. Typically, IPP is 20% to 40% of the full load current. When running diode emulation mode, the maximum ripple current should be less than twice the minimum load current. For full synchronous operation, higher ripple current is acceptable. Higher ripple current allows for a smaller inductor size, but places more of a burden on the output capacitor to smooth the ripple current for low output ripple voltage. For this example, 40% ripple current was chosen for a smaller sized inductor. L= 5V 0.4 x 7A x 250kHz x 1- 5V = 6.5 PH 60V (9) The nearest standard value of 6 µH will be used. The inductor must be rated for the peak current to prevent saturation. During normal operation, the peak current occurs at maximum load current plus maximum ripple. During overload conditions with properly scaled component values, the peak current is limited to VCS(TH) / RS (See next section). At the maximum input voltage with a shorted output, the valley current must fall below VCS(TH) / RS before the high-side MOSFET is allowed to turn on. The peak current in steady state will increase to VIN(MAX) x tON(min) / L above this level. The chosen inductor must be evaluated for this condition, especially at elevated temperature where the saturation current rating may drop significantly. CURRENT SENSE RESISTOR The current limit is set by the current sense resistor value (RS). ILIM = VCS(TH) RS (10) For a 5V output, the maximum current sense signal occurs at the minimum input voltage, so RS is calculated from: VCS(TH) RS d IO + VOUT 2 x L x fSW x 1+ VOUT VIN(MIN) (11) For this example VCCX = 0V, so VCS(TH) = 0.11V. The current sense resistor is calculated as: RS d 0.11V 5V 7A + 2 x 6 PH x 250 kHz x 1+ 5V 7V d 0.011: (12) The next lowest standard value of 10 mΩ was chosen for RS. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 19 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com RAMP CAPACITOR With the inductor and sense resistor value selected, the value of the ramp capacitor (CRAMP) necessary for the emulation ramp circuit is: CRAMP , gm x L A x RS (13) Where L is the value of the output inductor in Henrys, gm is the ramp generator transconductance (5 µA/V), and A is the current sense amplifier gain (10 V/V). For the 5V output design example, the ramp capacitor is calculated as: CRAMP = 5 PA/V x 6 PH 10V/V x 10 m: = 300 pF (14) The next lowest standard value of 270 pF was selected for CRAMP. A COG type capacitor with 5% or better tolerance is recommended. OUTPUT CAPACITORS The output capacitors smooth the inductor ripple current and provide a source of charge for transient loading conditions. For this design example, five 100 µF ceramic capacitors where selected. Ceramic capacitors provide very low equivalent series resistance (ESR), but can exhibit a significant reduction in capacitance with DC bias. From the manufacturer’s data, the ESR at 250 kHz is 2 mΩ / 5 = 0.4 mΩ, with a 36% reduction in capacitance at 5V. This is verified by measuring the output ripple voltage and frequency response of the circuit. The fundamental component of the output ripple voltage is calculated as: 'VOUT = IPP x € ESR2 + 1 8 x fSW x COUT 2 (15) With typical values for the 5V design example: 'VOUT = 3A x 0.4 m:2 + 1 8 x 250 kHz x 320 PF 2 'VOUT = 4.8 mV (16) INPUT CAPACITORS The regulator supply voltage has a large source impedance at the switching frequency. Good quality input capacitors are necessary to limit the ripple voltage at the VIN pin while supplying most of the switch current during the on-time. When the buck switch turns on, the current into the switch steps to the valley of the inductor current waveform, ramps up to the peak value, and then drops to zero at turn-off. The input capacitors should be selected for RMS current rating and minimum ripple voltage. A good approximation for the required ripple current rating is IRMS > IOUT / 2. Quality ceramic capacitors with a low ESR were selected for the input filter. To allow for capacitor tolerances and voltage rating, four 2.2 µF, 100V ceramic capacitors were used for the typical application circuit. With ceramic capacitors, the input ripple voltage will be triangular and peak at 50% duty cycle. Taking into account the capacitance change with DC bias, the input ripple voltage is approximated as: 'VIN = IOUT 4 x fSW x CIN = 7A 4 x 250 kHz x 7 PF = 1V (17) When the converter is connected to an input power source, a resonant circuit is formed by the line impedance and the input capacitors. If step input voltage transients are expected near the maximum rating of the LM5116WG, a careful evaluation of the ringing and possible overshoot at the device VIN pin should be completed. To minimize overshoot make CIN > 10 x LIN. The characteristic source impedance and resonant frequency are: ZS = 20 LIN CIN fS = 1 2S LIN x CIN (18) Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 The converter exhibits a negative input impedance which is lowest at the minimum input voltage: ZIN = - VIN2 POUT (19) The damping factor for the input filter is given by: G= 1 2 RIN + ESR ZS + ZS ZIN (20) where RIN is the input wiring resistance and ESR is the series resistance of the input capacitors. The term ZS/ZIN will always be negative due to ZIN. When δ = 1, the input filter is critically damped. This may be difficult to achieve with practical component values. With δ < 0.2, the input filter will exhibit significant ringing. If δ is zero or negative, there is not enough resistance in the circuit and the input filter will sustain an oscillation. When operating near the minimum input voltage, an aluminum electrolytic capacitor across CIN may be needed to damp the input for a typical bench test setup. Any parallel capacitor should be evaluated for its RMS current rating. The current will split between the ceramic and aluminum capacitors based on the relative impedance at the switching frequency. VCC CAPACITOR The primary purpose of the VCC capacitor (CVCC) is to supply the peak transient currents of the LO driver and bootstrap diode (D1) as well as provide stability for the VCC regulator. These current peaks can be several amperes. The recommended value of CVCC should be no smaller than 0.47 µF, and should be a good quality, low ESR, ceramic capacitor located at the pins of the IC to minimize potentially damaging voltage transients caused by trace inductance. A value of 1 µF was selected for this design. BOOTSTRAP CAPACITOR The bootstrap capacitor (CHB) between the HB and SW pins supplies the gate current to charge the high-side MOSFET gate at each cycle’s turn-on as well as supplying the recovery charge for the bootstrap diode (D1). These current peaks can be several amperes. The recommended value of the bootstrap capacitor is at least 0.1 µF, and should be a good quality, low ESR, ceramic capacitor located at the pins of the IC to minimize potentially damaging voltage transients caused by trace inductance. The absolute minimum value for the bootstrap capacitor is calculated as: Qg CHB t 'VHB (21) Where Qg is the high-side MOSFET gate charge and ΔVHB is the tolerable voltage droop on CHB, which is typically less than 5% of VCC. A value of 1 µF was selected for this design. SOFT-START CAPACITOR The capacitor at the SS pin (CSS) determines the soft-start time, which is the time for the reference voltage and the output voltage to reach the final regulated value. The soft-start time tSS should be substantially longer than the time required to charge COUT to VOUT at the maximum output current. To meet this requirement: tSS > VOUT x COUT / (ICURRENT LIMIT − IOUT) (22) The value of CSS for a given time is determined from: CSS = tSS x 10 PA (23) 1.215V For this application, a value of 0.01 µF was chosen for a soft-start time of 1.2 ms. OUTPUT VOLTAGE DIVIDER RFB1 and RFB2 set the output voltage level, the ratio of these resistors is calculated from: RFB2 VOUT -1 = RFB1 1.215V (24) RFB1 is typically 1.21 kΩ for a divider current of 1 mA. The divider current can be reduced to 100 µA with RFB1=12.1 kΩ. For the 5V output design example used here, RFB1 = 1.21 kΩ and RFB2 = 3.74 kΩ. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 21 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com UVLO DIVIDER A voltage divider and filter can be connected to the UVLO pin to set a minimum operating voltage VIN(MIN) for the regulator. If this feature is required, the following procedure can be used to determine appropriate resistor values for RUV2, RUV1 and CFT. 1. RUV2 must be large enough such that in the event of a current limit, the internal UVLO switch can pull UVLO < 200mV. This can be guaranteed if: RUV2 > 500 x VIN(MAX) where • VIN(MAX) is the maximum input voltage and RUV2 is in ohms. 2. With an appropriate value for RUV2, RUV1 can be selected using the following equation: RUV1 = 1.215 x RUV2 VIN(MIN) + (5 PA x RUV2) - 1.215 where • VIN(MIN) is the desired shutdown voltage. 3. Capacitor CFT provides filtering for the divider and determines the off-time of the “hiccup” duty cycle during current limit. When CFT is used in conjunction with the voltage divider, a diode across the top resistor should be used to discharge CFT in the event of an input under-voltage condition. tOFF = - RUV1 x RUV2 RUV1 + RUV2 x CFT x ln 1 - 1.215 x (RUV1 + RUV2) VIN x RUV1 If under-voltage shutdown is not required, RUV1 and RUV2 can be eliminated and the off-time becomes: tOFF = CFT x 1.215V 5 PA (25) The voltage at the UVLO pin should never exceed 16V when using an external set-point divider. It may be necessary to clamp the UVLO pin at high input voltages. For the design example, RUV2 = 102 kΩ and RUV1 = 21 kΩ for a shut-down voltage of 6.6V. If sustained short circuit protection is required, CFT ≥ 1 µF will limit the short circuit power dissipation. D2 may be installed when using CFT with RUV1 and RUV2. MOSFETs Selection of the power MOSFETs is governed by the same tradeoffs as switching frequency. Breaking down the losses in the high-side and low-side MOSFETs is one way to determine relative efficiencies between different devices. When using discrete SO-8 MOSFETs the LM5116WG is most efficient for output currents of 2A to 10A. Losses in the power MOSFETs can be broken down into conduction loss, gate charging loss, and switching loss. Conduction, or I2R loss PDC, is approximately: PDC(HO-MOSFET) = D x (IO2 x RDS(ON) x 1.3) PDC(LO-MOSFET) = (1 - D) x (IO2 x RDS(ON) x 1.3) (26) (27) Where D is the duty cycle. The factor 1.3 accounts for the increase in MOSFET on-resistance due to heating. Alternatively, the factor of 1.3 can be ignored and the on-resistance of the MOSFET can be estimated using the RDS(ON) vs Temperature curves in the MOSFET datasheet. Gate charging loss, PGC, results from the current driving the gate capacitance of the power MOSFETs and is approximated as: PGC = n x VCC x Qg x fSW (28) Qg refer to the total gate charge of an individual MOSFET, and ‘n’ is the number of MOSFETs. If different types of MOSFETs are used, the ‘n’ term can be ignored and their gate charges summed to form a cumulative Qg. Gate charge loss differs from conduction and switching losses in that the actual dissipation occurs in the LM5116WG and not in the MOSFET itself. Further loss in the LM5116WG is incurred as the gate driving current is supplied by the internal linear regulator. The gate drive current supplied by the VCC regulator is calculated as: IGC = (Qgh + Qgl) x fSW (29) Where Qgh + Qgl represent the gate charge of the HO and LO MOSFETs at VGS = VCC. To ensure start-up, IGC should be less than the VCC current limit rating of 15 mA minimum when powered by the internal 7.4V regulator. Failure to observe this rating may result in excessive MOSFET heating and potential damage. The IGC run current may exceed 15 mA when VCC is powered by VCCX. 22 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Switching loss occurs during the brief transition period as the MOSFET turns on and off. During the transition period both current and voltage are present in the channel of the MOSFET. The switching loss can be approximated as: PSW = 0.5 x VIN x IO x (tR + tF) x fSW (30) Where tR and tF are the rise and fall times of the MOSFET. Switching loss is calculated for the high-side MOSFET only. Switching loss in the low-side MOSFET is negligible because the body diode of the low-side MOSFET turns on before the MOSFET itself, minimizing the voltage from drain to source before turn-on. For this example, the maximum drain-to-source voltage applied to either MOSFET is 60V. VCC provides the drive voltage at the gate of the MOSFETs. The selected MOSFETs must be able to withstand 60V plus any ringing from drain to source, and be able to handle at least VCC plus ringing from gate to source. A good choice of MOSFET for the 60V input design example is the Si7850DP. It has an RDS(ON) of 20 mΩ, total gate charge of 14 nC, and rise and fall times of 10 ns and 12 ns respectively. In applications where a high step-down ratio is maintained for normal operation, efficiency may be optimized by choosing a high-side MOSFET with lower Qg, and low-side MOSFET with lower RDS(ON). For higher voltage MOSFETs which are not true logic level, it is important to use the UVLO feature. Choose a minimum operating voltage which is high enough for VCC and the bootstrap (HB) supply to fully enhance the MOSFET gates. This will prevent operation in the linear region during power-on or power-off which can result in MOSFET failure. Similar consideration must be made when powering VCCX from the output voltage. For the high-side MOSFET, the gate threshold should be considered and careful evaluation made if the gate threshold voltage exceeds the HO driver UVLO. MOSFET SNUBBER A resistor-capacitor snubber network across the low-side MOSFET reduces ringing and spikes at the switching node. Excessive ringing and spikes can cause erratic operation and couple spikes and noise to the output. Selecting the values for the snubber is best accomplished through empirical methods. First, make sure the lead lengths for the snubber connections are very short. Start with a resistor value between 5Ω and 50Ω. Increasing the value of the snubber capacitor results in more damping, but higher snubber losses. Select a minimum value for the snubber capacitor that provides adequate damping of the spikes on the switch waveform at high load. ERROR AMPLIFIER COMPENSATION RCOMP, CCOMP and CHF configure the error amplifier gain characteristics to accomplish a stable voltage loop gain. One advantage of current mode control is the ability to close the loop with only two feedback components, RCOMP and CCOMP. The voltage loop gain is the product of the modulator gain and the error amplifier gain. For the 5V output design example, the modulator is treated as an ideal voltage-to-current converter. The DC modulator gain of the LM5116WG can be modeled as: DC Gain(MOD) = RLOAD / (A x RS) (31) The dominant low frequency pole of the modulator is determined by the load resistance (RLOAD) and output capacitance (COUT). The corner frequency of this pole is: fP(MOD) = 1 / (2π x RLOAD x COUT) (32) For RLOAD = 5V / 7A = 0.714Ω and COUT = 320 µF (effective) then fP(MOD) = 700 Hz DC Gain(MOD) = 0.714Ω / (10 x 10 mΩ) = 7.14 = 17 dB For the 5V design example the modulator gain vs. frequency characteristic was measured as shown in Figure 36. Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 23 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Figure 36. Modulator Gain and Phase Components RCOMP and CCOMP configure the error amplifier as a type II configuration. The DC gain of the amplifier is 80 dB which has a pole at low frequency and a zero at fZEA = 1 / (2π x RCOMP x CCOMP). The error amplifier zero cancels the modulator pole leaving a single pole response at the crossover frequency of the voltage loop. A single pole response at the crossover frequency yields a very stable loop with 90° of phase margin. For the design example, a target loop bandwidth (crossover frequency) of one-tenth the switching frequency or 25 kHz was selected. The compensation network zero (fZEA) should be selected at least an order of magnitude less than the target crossover frequency. This constrains the product of RCOMP and CCOMP for a desired compensation network zero 1 / (2π x RCOMP x CCOMP) to be 2.5 kHz. Increasing RCOMP, while proportionally decreasing CCOMP, increases the error amp gain. Conversely, decreasing RCOMP while proportionally increasing CCOMP, decreases the error amp gain. For the design example CCOMP was selected as 3300 pF and RCOMP was selected as 18 kΩ. These values configure the compensation network zero at 2.7 kHz. The error amp gain at frequencies greater than fZEA is: RCOMP / RFB2, which is approximately 4.8 (13.6 dB). Figure 37. Error Amplifier Gain and Phase The overall voltage loop gain can be predicted as the sum (in dB) of the modulator gain and the error amp gain. 24 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Figure 38. Overall Voltage Loop Gain and Phase If a network analyzer is available, the modulator gain can be measured and the error amplifier gain can be configured for the desired loop transfer function. If a network analyzer is not available, the error amplifier compensation components can be designed with the guidelines given. Step load transient tests can be performed to verify acceptable performance. The step load goal is minimum overshoot with a damped response. CHF can be added to the compensation network to decrease noise susceptibility of the error amplifier. The value of CHF must be sufficiently small since the addition of this capacitor adds a pole in the error amplifier transfer function. This pole must be well beyond the loop crossover frequency. A good approximation of the location of the pole added by CHF is: fP2 = fZEA x CCOMP / CHF. The value of CHF was selected as 100 pF for the design example. PCB BOARD LAYOUT and THERMAL CONSIDERATIONS In a buck regulator the primary switching loop consists of the input capacitor, MOSFETs and current sense resistor. Minimizing the area of this loop reduces the stray inductance and minimizes noise and possible erratic operation. The input capacitor should be placed as close as possible to the MOSFETs, with the VIN side of the capacitor connected directly to the high-side MOSFET drain, and the GND side of the capacitor connected as close as possible to the low-side source or current sense resistor ground connection. A ground plane in the PC board is recommended as a means to connect the quiet end (input voltage ground side) of the input filter capacitors to the output filter capacitors and the PGND pin of the regulator. Connect all of the low power ground connections (CSS, RT, CRAMP) directly to the regulator AGND pin. Connect the AGND and PGND pins together through to a topside copper area covering the entire underside of the device. Place several vias in this underside copper area to the ground plane. The highest power dissipating components are the two power MOSFETs. The easiest way to determine the power dissipated in the MOSFETs is to measure the total conversion losses (PIN - POUT), then subtract the power losses in the output inductor and any snubber resistors. The resulting power losses are primarily in the switching MOSFETs. If a snubber is used, the power loss can be estimated with an oscilloscope by observation of the resistor voltage drop at both turn-on and turn-off transitions. Assuming that the RC time constant is << 1 / fSW. P = C x V2 x fSW (33) Selecting MOSFETs with exposed pads will aid the power dissipation of these devices. Careful attention to RDS(ON) at high temperature should be observed. Also, at 250 kHz, a MOSFET with low gate capacitance will result in lower switching losses. Comprehensive Equations CURRENT SENSE RESISTOR AND RAMP CAPACITOR T = 1 / fSW, gm = 5 µA/V, A = 10 V/V. IOUT is the maximum output current at current limit. General Method for VOUT < 5V: Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 25 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com VCS(TH) RS = IOUT - VOUT x T 2xL x 1- VOUT VIN(MIN) + VOUT x T L 1+ x 1+ CRAMP = gm x L x 1+ A x RS 5 - VOUT VIN(MIN) 5 - VOUT VIN(MAX) (34) 5 - VOUT VIN(MAX) (35) General Method for 5V < VOUT < 7.5V: VCS(TH) RS = IOUT - VOUT x T 2xL gm x L CRAMP = A x RS x 1- x 1+ VOUT VIN(MIN) + VOUT x T L (36) 5 - VOUT VIN(MIN) (37) Best Performance Method: This minimizes the current limit deviation due to changes in line voltage, while maintaining near optimal slope compensation. Calculate optimal slope current, IOS = (VOUT / 3) x 10 µA/V. For example, at VOUT = 7.5V, IOS = 25 µA. VCS(TH) RS = VOUT x T IOUT + CRAMP = IOS x L VOUT x A x RS L (38) Calculate VRAMP at the nominal input voltage. VOUT VRAMP = VIN x ((VIN ± VOUT) x gm + IOS) x T CRAMP (39) For VOUT > 7.5V, install a resistor from the RAMP pin to VCC. RRAMP = VCC - VRAMP IOS - 25 PA (40) VCC RRAMP RAMP CRAMP Figure 39. RRAMP to VCC for VOUT > 7.5V For VOUT < 7.5V, a negative VCC is required. This can be made with a simple charge pump from the LO gate output. Install a resistor from the RAMP pin to the negative VCC. RRAMP = 26 VCC ± 0.5V + VRAMP 25 PA - IOS (41) Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 LO 10 nF 1N914 RRAMP 10 nF RAMP -VCC CRAMP Figure 40. RRAMP to -VCC for VOUT < 7.5V If a large variation is expected in VCC, say for VIN < 11V, a Zener regulator may be added to supply a constant voltage for RRAMP. MODULATOR TRANSFER FUNCTION The following equations can be used to calculate the control-to-output transfer function: VOUT VCOMP Km = = RLOAD x A x RS 1+ 1+ Km x A x RS s ZP s ZZ x 1+ s s2 + Zn x Q Zn2 (42) 1 (D ± 0.5) x A x RS x T gm x T KSL = Se = x RLOAD L ZZ = 1+ 1 VSL = CRAMP 1 COUT x ESR + (1 - 2 x D) x KSL + mC = Se Sn (43) IOS x T CRAMP (44) 1 x + ZP = COUT RLOAD Km x A x RS 1 1 (VIN ± VOUT) x KSL + VSL T VSL VIN Sn = Q= S Zn = T (45) VIN x A x RS L 1 S x (mC ± 0.5) (46) Km is the effective DC gain of the modulating comparator. The duty cycle D = VOUT / VIN. KSL is the proportional slope compensation term. VSL is the fixed slope compensation term. Slope compensation is set by mc, which is the ratio of the external ramp to the natural ramp. The switching frequency sampling gain is characterized by ωn and Q, which accounts for the high frequency inductor pole. For VSL without RRAMP, use IOS = 25 µA For VSL with RRAMP to VCC, use IOS = 25 µA + VCC/RRAMP For VSL with RRAMP to -VCC, use IOS = 25 µA - VCC/RRAMP ERROR AMPLIFIER TRANSFER FUNCTION The following equations are used to calculate the error amplifier transfer function: VCOMP VOUT(FB) 1 = -GEA(S) x GEA(S) 1 s 1+ + x 1+ KFB AOL ZBW (47) Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 27 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 1+ GEA(S) = ZZEA = s ZZEA s s x 1+ Z HF ZO 1 CCOMP x RCOMP ZHF = KFB = www.ti.com RFB1 RFB1 + RFB2 (48) ZO = 1 (CHF + CCOMP) x RFB2 (CHF + CCOMP) CHF x CCOMP x RCOMP (49) Where AOL = 10,000 (80 dB) and ωBW = 2π x fBW. GEA(S) is the ideal error amplifier gain, which is modified at DC and high frequency by the open loop gain of the amplifier and the feedback divider ratio. 28 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Figure 41. 5V 7A Typical Application Schematic Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 29 LM5116WG SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 www.ti.com Table 1. Bill of Materials for 7V-60V Input, 5V 7A Output, 250kHz ID Part Number Type Size Parameters Qty Vendor C1, C2, C14 C2012X7R1E105K Capacitor, Ceramic 0805 1µF, 25V, X7R 3 TDK C3 VJ0603Y103KXAAT Capacitor, Ceramic 0603 0.01µF, 50V, X7R 1 Vishay C4 VJ0603A271JXAAT Capacitor, Ceramic 0603 270pF, 50V, COG, 5% 1 Vishay C5, C15 VJ0603Y101KXAT W1BC Capacitor, Ceramic 0603 100pF, 50V, X7R 2 Vishay C6 VJ0603Y332KXXAT Capacitor, Ceramic 0603 3300pF, 25V, X7R 1 Vishay Capacitor, Ceramic 0603 Not Used 0 2.2µF, 100V X7R 4 TDK C7 C8, C9, C10, C11 C4532X7R2A225M Capacitor, Ceramic 1812 C12 C3225X7R2A105M Capacitor, Ceramic 1210 1µF, 100V X7R 1 TDK C13 C2012X7R2A104M Capacitor, Ceramic 0805 0.1µF, 100V X7R 1 TDK C16, C17, C18, C19, C20 C4532X6S0J107M Capacitor, Ceramic 1812 100µF, 6.3V, X6S, 105°C 5 TDK C21, C22 Capacitor, Tantalum D Case Not Used 0 C23 Capacitor, Ceramic 0805 Not Used 0 D1 CMPD2003 Diode, Switching SOT-23 200mA, 200V 1 Central Semi D2 CMPD2003 Diode, Switching SOT-23 Not Used 0 Central Semi JMP1 Connector, Jumper 2 pin sq. post 1 L1 HC2LP-6R0 Inductor 6µH, 16.5A 1 Cooper P1-P4 1514-2 Turret Terminal 4 Keystone TP1-TP5 5012 Test Point .040” dia. 5 Keystone Q1, Q2 Si7850DP N-CH MOSFET SO-8 Power PAK 10.3A, 60V 2 Vishay Siliconix R1 CRCW06031023F Resistor 0603 102kΩ, 1% 1 Vishay R2 CRCW06032102F Resistor 0603 21.0kΩ, 1% 1 Vishay R3 CRCW06033741F Resistor 0603 3.74kΩ, 1% 1 Vishay R4 CRCW06031211F Resistor 0603 1.21kΩ, 1% 1 Vishay R5 Resistor 0603 Not Used 0 R6, R7 CRCW06030R0J Resistor 0603 0Ω 2 Vishay R8 CRCW0603103J Resistor 0603 10kΩ, 5% 1 Vishay R9 CRCW06031242F Resistor 0603 12.4kΩ, 1% 1 Vishay R10 CRCW0603183J Resistor 0603 18kΩ, 5% 1 Vishay R11 LRC-LRF2010-01R010-F Resistor 2010 0.010Ω, 1% 1 IRC Resistor 0603 Not Used 0 Resistor 0603 1MΩ, 5% 1 Resistor 1206 Not Used 0 Synchronous Buck Controller CPGA-20 R12 R13 CRCW0603105J R14 U1 30 .090” dia. LM5116WG Submit Documentation Feedback 1 Vishay TI Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG LM5116WG www.ti.com SNVS599D – OCTOBER 2008 – REVISED FEBRUARY 2013 Changes from Revision B (February 2013) to Revision C • Page Changed layout of National Data Sheet to TI format .......................................................................................................... 30 Submit Documentation Feedback Copyright © 2008–2013, Texas Instruments Incorporated Product Folder Links: LM5116WG 31 PACKAGE OPTION ADDENDUM www.ti.com 23-May-2013 PACKAGING INFORMATION Orderable Device Status (1) LM5116WG/NOPB ACTIVE Package Type Package Pins Package Drawing Qty CFP NAR 20 30 Eco Plan Lead/Ball Finish (2) Pb-Free (RoHS Exempt) MSL Peak Temp Op Temp (°C) Device Marking (3) Call TI Level-1-NA-UNLIM (4/5) -40 to 125 LM5116WG (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. (4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device. (5) Multiple Device Markings will be inside parentheses. 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