Sample & Buy Product Folder Technical Documents Support & Community Tools & Software LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 LM2735-xx 520-kHz and 1.6-MHz Space-Efficient Boost and SEPIC DC-DC Regulator 1 Features 3 Description * * * The LM2735 device is an easy-to-use, space-efficient 2.1-A low-side switch regulator, ideal for Boost and SEPIC DC-DC regulation. The device provides all the active functions to provide local DC-DC conversion with fast-transient response and accurate regulation in the smallest PCB area. Switching frequency is internally set to either 520 kHz or 1.6 MHz, allowing the use of extremely small surface mount inductor and chip capacitors, while providing efficiencies of up to 90%. Current-mode control and internal compensation provide ease-of-use, minimal component count, and high-performance regulation over a wide range of operating conditions. External shutdown features an ultra-low standby current of 80 nA, ideal for portable applications. Tiny SOT-23, WSON, and MSOP-PowerPAD packages provide space savings. Additional features include internal soft start, circuitry to reduce inrush current, pulse-bypulse current limit, and thermal shutdown. 1 * * * * * * * Input Voltage Range: 2.7 V to 5.5 V Output Voltage Range: 3 V to 24 V 2.1-A Switch Current Over Full Temperature Range Current-Mode Control Logic High Enable Pin Ultra-Low Standby Current of 80 nA in Shutdown 170-m NMOS Switch 2% Feedback Voltage Accuracy Ease-of-Use, Small Total Solution Size - Internal Soft Start - Internal Compensation - Two Switching Frequencies - 520 kHz (LM2735-Y) - 1.6 MHz (LM2735-X) - Uses Small Surface Mount Inductors and Chip Capacitors - Tiny SOT-23, WSON, and MSOP-PowerPAD Packages LM2735-Q1 is AEC-Q100 Grade 1 Qualified and is Manufactured on an Automotive Grade Flow Device Information(1) PART NUMBER LM2735 LM2735-Q1 2 Applications * * * * * * PACKAGE BODY SIZE (NOM) WSON (6) 3.00 mm x 3.00 mm SOT-23 (5) 1.60 mm x 2.90 mm MSOP-PowerPAD (8) 3.00 mm x 3.00 mm WSON (6) 3.00 mm x 3.00 mm SOT-23 (5) 1.60 mm x 2.90 mm (1) For all available packages, see the orderable addendum at the end of the data sheet. LCD Display Backlighting For Portable Applications OLED Panel Power Supply USB-Powered Devices Digital Still and Video Cameras White LED Current Source Automotive space Typical Boost Application Circuit Efficiency vs Load Current VO = 12 V VIN 2.7V-5.5V L1 12V D1 R2 R3 4 3 C2 2 5 C3 R1 1 C1 GND 1 An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications, intellectual property matters and other important disclaimers. PRODUCTION DATA. LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Table of Contents 1 2 3 4 5 6 7 Features .................................................................. Applications ........................................................... Description ............................................................. Revision History..................................................... Pin Configuration and Functions ......................... Specifications......................................................... 1 1 1 2 3 4 6.1 6.2 6.3 6.4 6.5 6.6 6.7 4 4 4 4 4 5 7 Absolute Maximum Ratings ...................................... ESD Ratings: LM2735 .............................................. ESD Ratings: LM2735-Q1 ........................................ Recommended Operating Conditions....................... Thermal Information .................................................. Electrical Characteristics........................................... Typical Characteristics .............................................. Detailed Description .............................................. 9 7.1 7.2 7.3 7.4 Overview ................................................................... 9 Functional Block Diagram ....................................... 11 Feature Description................................................. 11 Device Functional Modes........................................ 14 8 Application and Implementation ........................ 14 8.1 Application Information............................................ 14 8.2 Typical Applications ................................................ 14 9 Power Supply Recommendations...................... 37 10 Layout................................................................... 37 10.1 Layout Guidelines ................................................. 37 10.2 Layout Examples................................................... 38 10.3 Thermal Considerations ........................................ 39 11 Device and Documentation Support ................. 48 11.1 11.2 11.3 11.4 11.5 11.6 11.7 Device Support...................................................... Documentation Support ........................................ Related Links ........................................................ Community Resources.......................................... Trademarks ........................................................... Electrostatic Discharge Caution ............................ Glossary ................................................................ 48 48 48 48 48 48 48 12 Mechanical, Packaging, and Orderable Information ........................................................... 49 4 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision F (April 2013) to Revision G * Page Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information section. ................................................................................................. 1 Changes from Revision E (April 2013) to Revision F * 2 Page Changed layout of National Data Sheet to TI format ........................................................................................................... 33 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 5 Pin Configuration and Functions DBV Package 5-Pin SOT-23 Top View SW 1 DGN Package 8-Pin MSOP-PowerPAD Top View 5 VIN NC 1 8 NC PGND 2 7 SW VIN 3 6 AGND EN 4 5 FB GND 2 FB 3 4 EN NGG Package 6-Pin WSON Top View PGND 1 6 SW VIN 2 5 AGND EN 3 4 FB Pin Functions PIN NAME SOT-23 WSON MSOPPowerPAD I/O DESCRIPTION AGND -- 5 6 PWR Signal ground pin. Place the bottom resistor of the feedback network as close as possible to this pin and pin 4. For MSOP-PowerPAD, place the bottom resistor of the feedback network as close as possible to this pin and pin 5 EN 4 3 4 I Shutdown control input. Logic high enables operation. Do not allow this pin to float or be greater than VIN + 0.3 V. FB 3 4 5 I Feedback pin. Connect FB to external resistor-divider to set output voltage. GND 2 DAP DAP PWR NC -- -- 1, 8 -- PGND -- 1 2 PWR SW 1 6 7 O VIN 5 2 3 PWR Signal and power ground pin. Place the bottom resistor of the feedback network as close as possible to this pin. For WSON, connect to pin 1 and pin 5 on top layer. Place 4-6 vias from DAP to bottom layer GND plane. No Connect Power ground pin. Place PGND and output capacitor GND close together. Output switch. Connect to the inductor, output diode. Supply voltage for power stage, and input supply voltage. Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 3 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 6 Specifications 6.1 Absolute Maximum Ratings (1) MIN MAX UNIT VIN -0.5 7 V SW Voltage -0.5 26.5 V FB Voltage -0.5 3 V EN Voltage -0.5 7 V Junction Temperature (2) 150 C Soldering Information, Infrared/Convection Reflow (15 s) 220 C 150 C Storage Temperature (1) (2) -65 If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and specifications. Thermal shutdown will occur if the junction temperature exceeds the maximum junction temperature of the device. 6.2 ESD Ratings: LM2735 VALUE Human body model (HBM), per ANSI/ESDA/JEDEC JS-001 V(ESD) (1) (2) (3) Electrostatic discharge (1) (2) UNIT 2000 Charged device model (CDM), per JEDEC specification JESD22C101 (3) 1000 V JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. Manufacturing with less than 500-V HBM is possible if necessary precautions are taken. The human body model is a 100-pF capacitor discharged through a 1.5-k resistor into each pin. JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. Manufacturing with less than 250-V CDM is possible if necessary precautions are taken. 6.3 ESD Ratings: LM2735-Q1 VALUE V(ESD) (1) Electrostatic discharge Human body model (HBM), per AEC Q100-002 (1) 2000 Charged device model (CDM), per AEC Q100-011 1000 UNIT V AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification. 6.4 Recommended Operating Conditions over operating free-air temperature range (unless otherwise noted) MIN VIN VSW VEN (1) Junction Temperature Range Power Dissipation (1) NOM MAX UNIT 2.7 5.5 V 3 24 V 0 VIN V -40 125 C 400 mW (Internal) SOT-23 Do not allow this pin to float or be greater than VIN + 0.3 V. 6.5 Thermal Information LM2735, LM2735-Q1 THERMAL METRIC (1) (2) LM2735 NGG (WSON) DBV (SOT-23) DGN (MSOPPowerPAD) 6 PINS 5 PINS 8 PINS UNIT RJA Junction-to-ambient thermal resistance 54.9 164.2 59 C/W RJC(top) Junction-to-case (top) thermal resistance (2) 50.9 115.3 51.2 C/W RJB Junction-to-board thermal resistance 29.3 27 35.8 C/W (1) (2) 4 For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report, SPRA953. Applies for packages soldered directly onto a 3" x 3" PC board with 2-oz. copper on 4 layers in still air. Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Thermal Information (continued) LM2735, LM2735-Q1 THERMAL METRIC (1) LM2735 NGG (WSON) DBV (SOT-23) DGN (MSOPPowerPAD) 8 PINS UNIT 6 PINS 5 PINS JT Junction-to-top characterization parameter 0.7 12.8 2.7 C/W JB Junction-to-board characterization parameter 29.4 26.5 35.6 C/W RJC(bot) Junction-to-case (bottom) thermal resistance 9.3 N/A 7.3 C/W 6.6 Electrical Characteristics Limits are for TJ = 25C. Minimum and Maximum limits are specified through test, design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25C, and are provided for reference purposes only. VIN = 5 V unless otherwise indicated under the Conditions column. PARAMETER TEST CONDITIONS -40C to TJ 125C (SOT-23) 0C to TJ 125C (SOT-23) -40C to TJ 125C (WSON) VFB Feedback Voltage -0C to TJ 125C (WSON) VFB/VIN Feedback Voltage Line Regulation IFB Feedback Input Bias Current Soft Start 1.255 TJ = -40C to 125C 1.229 TJ = -40C to 125C 1.281 1.22 1.29 1.255 TJ = -40C to 125C 1.23 1.28 0.06 %/V 0.1 1 TJ = 25C 1200 TJ = 25C 2000 520 TJ = -40C to 125C 360 TJ = 25C 680 88% TJ = 25C 99% TJ = -40C to 125C 91% 2% TJ = 25C 170 TJ = -40C to 125C 330 TJ = 25C 190 TJ = -40C to 125C m 350 TJ = 25C 3 2.1 4 Product Folder Links: LM2735 LM2735-Q1 kHz 96% TJ = -40C to 125C Copyright (c) 2007-2015, Texas Instruments Incorporated A 1600 TJ = -40C to 125C TJ = -40C to 125C V 1.255 5% WSON SS TJ = 25C 1.285 LM2735-Y Switch ON-Resistance Switch Current Limit 1.225 LM2735-X SOT-23 and MSOP-PowerPAD ICL TJ = -40C to 125C TJ = -40C to 125C LM2735-Y RDS(ON) 1.274 1.255 TJ = 25C Maximum Duty Cycle Minimum Duty Cycle 1.28 1.236 TJ = 25C VIN = 2.7 V to 5.5 V Switching Frequency MAX UNIT 1.255 TJ = -40C to 125C TJ = 25C LM2735-X DMIN 1.23 TJ = 25C 0C to TJ 125C (MSOPPowerPAD) TYP 1.255 TJ = -40C to 125C -40C to TJ 125C (MSOP-PowerPAD) LM2735-Y DMAX TJ = 25C TJ = 25C LM2735-X FSW MIN Submit Documentation Feedback A ms 5 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Electrical Characteristics (continued) Limits are for TJ = 25C. Minimum and Maximum limits are specified through test, design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25C, and are provided for reference purposes only. VIN = 5 V unless otherwise indicated under the Conditions column. PARAMETER TEST CONDITIONS LM2735-X Quiescent Current (switching) IQ LM2735-Y Quiescent Current (shutdown) Undervoltage Lockout VIN Falling TYP MAX UNIT 7 TJ = -40C to 125C 11 TJ = 25C 3.4 TJ = -40C to 125C mA 7 All Options VEN = 0 V VIN Rising UVLO MIN TJ = 25C 80 TJ = 25C nA 2.3 TJ = -40C to 125C 2.65 TJ = 25C 1.9 TJ = -40C to 125C V 1.7 Shutdown Threshold Voltage See Enable Threshold Voltage See (1), TJ = -40C to 125C I-SW Switch Leakage VSW = 24 V 1 A I-EN Enable Pin Current Sink/Source 100 nA VEN_TH TSD (1) (2) 6 (1) , TJ = -40C to 125C 0.4 V 1.8 Thermal Shutdown Temperature (2) 160 Thermal Shutdown Hysteresis 10 C Do not allow this pin to float or be greater than VIN + 0.3 V. Thermal shutdown will occur if the junction temperature exceeds the maximum junction temperature of the device. Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 6.7 Typical Characteristics Figure 1. Current Limit vs Temperature Figure 2. FB Pin Voltage vs Temperature Figure 3. Oscillator Frequency vs Temperature - "X" Figure 4. Oscillator Frequency vs Temperature - "Y" Figure 5. Typical Maximum Output Current vs VIN Figure 6. RDSON vs Temperature Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 7 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Typical Characteristics (continued) VO = 20 V VO = 20 V Figure 7. LM2735X Efficiency vs Load Current VO = 12 V 8 Figure 8. LM2735Y Efficiency vs Load Current VO = 12 V Figure 9. LM2735X Efficiency vs Load Current Figure 10. LM2735Y Efficiency vs Load Current Figure 11. Output Voltage Load Regulation Figure 12. Output Voltage Line Regulation Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 7 Detailed Description 7.1 Overview The LM2735 device is highly efficient and easy-to-use switching regulator for boost and SEPIC applications. The device provides regulated DC output with fast transient response. Device architecture (current mode control) and internal compensation enable solutions with minimum number of external components. Additionally high switching frequency allows for use of small external passive components (chip capacitors, SMD inductors) and enables power solutions with very small PCB area. LM2735 also provides features such as soft start, pulse-bypulse current-limit, and thermal shutdown. 7.1.1 Theory of Operation The LM2735 is a constant-frequency PWM boost regulator IC that delivers a minimum of 2.1 A peak switch current. The regulator has a preset switching frequency of either 520 kHz or 1.6 MHz. This high frequency allows the device to operate with small surface mount capacitors and inductors, resulting in a DC-DC converter that requires a minimum amount of board space. The LM2735 is internally compensated, so it is simple to use, and requires few external components. The device uses current-mode control to regulate the output voltage. The following operating description of the LM2735 will refer to the simplified internal block diagram (Functional Block Diagram), the simplified schematic (Figure 13), and its associated waveforms (Figure 14). The LM2735 supplies a regulated output voltage by switching the internal NMOS control switch at constant frequency and variable duty cycle. A switching cycle begins at the falling edge of the reset pulse generated by the internal oscillator. When this pulse goes low, the output control logic turns on the internal NMOS control switch. During this on-time, the SW pin voltage (VSW) decreases to approximately GND, and the inductor current (IL) increases with a linear slope. IL is measured by the current sense amplifier, which generates an output proportional to the switch current. The sensed signal is summed with the corrective ramp of the regulator and compared to the error amplifier's output, which is proportional to the difference between the feedback voltage and VREF. When the PWM comparator output goes high, the output switch turns off until the next switching cycle begins. During the switch off-time, inductor current discharges through diode D1, which forces the SW pin to swing to the output voltage plus the forward voltage (VD) of the diode. The regulator loop adjusts the duty cycle (D) to maintain a constant output voltage . I L (t) + VL (t) - D1 L1 I C (t) Control + VIN + Q1 VSW( t ) C1 VO(t) - Figure 13. Simplified Schematic Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 9 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Overview (continued) VO + VD Vsw (t) t VIN VL(t) t VIN - VOUT - VD I L (t) iL t I DIODE (t) t ( iL - - i OUT ) I Capacitor (t) t - i OUT 'v VOUT (t) DTS TS Figure 14. Typical Waveforms 10 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 7.2 Functional Block Diagram EN VIN ThermalSHDN Control Logic + UVLO = 2.3V Oscillator Corrective - Ramp SW + - FB cv S R R Q 1.6 MHz + VREF = 1.255V NMOS Internal Compensation ILIMIT Soft-Start ISENSE-AMP + - GND 7.3 Feature Description 7.3.1 Current Limit The LM2735 uses cycle-by-cycle current limiting to protect the internal NMOS switch. It is important to note that this current limit will not protect the output from excessive current during an output short circuit. The input supply is connected to the output by the series connection of an inductor and a diode. If a short circuit is placed on the output, excessive current can damage both the inductor and diode. 7.3.2 Thermal Shutdown Thermal shutdown limits total power dissipation by turning off the output switch when the IC junction temperature exceeds 160C. After thermal shutdown occurs, the output switch does not turn on until the junction temperature drops to approximately 150C. 7.3.3 Soft Start This function forces VOUT to increase at a controlled rate during start-up. During soft start, the error amplifier's reference voltage ramps to its nominal value of 1.255 V in approximately 4 ms. This forces the regulator output to ramp up in a more linear and controlled fashion, which helps reduce inrush current. 7.3.4 Compensation The LM2735 uses constant-frequency peak current mode control. This mode of control allows for a simple external compensation scheme that can be optimized for each application. A complicated mathematical analysis can be completed to fully explain the internal and external compensation of the LM2735, but for simplicity, a graphical approach with simple equations will be used. Below is a Gain and Phase plot of a LM2735 that produces a 12-V output from a 5-V input voltage. The Bode plot shows the total loop Gain and Phase without external compensation. Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 11 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Feature Description (continued) 80 180 gm-Pole 60 RC-Pole 90 40 dB 20 0 -20 Vi = 5V Vo = 12V Io = 500 mA Co = 10 PF Lo = 5 PH 0 gm-Zero -90 -40 RHP-Zero -60 -80 10 100 1k 10k 100k -180 1M FREQUENCY Figure 15. LM2735 Without External Compensation One can see that the crossover frequency is fine, but the phase margin at 0 dB is very low (22). A zero can be placed just above the crossover frequency so that the phase margin will be bumped up to a minimum of 45. Below is the same application with a zero added at 8 kHz. 80 60 40 gm-Pole RC-Pole 180 Vi = 5V Vo = 12V Io = 500 mA Co = 10 mF Lo = 5 mH 90 D = 0.625 Cf = 220 pF gm-zero 0 0 Fz-cf = 8 kHz RHP-Zero = 107 kHz -20 Fp-cf = 77 kHz Fp-rc = 660 Hz -90 -40 Ext (Cf) -Zero -60 Ext (Cf)-Pole RHP-Zero -180 -80 10 100 1k 10k 100k 1M dB 20 FREQUENCY Figure 16. LM2735 With External Compensation The simplest method to determine the compensation component value is as follows. Set the output voltage with the following equation. VOUT * - 1 x R1 R 2 = (c) VREF where * R1 is the bottom resistor and R2 is the resistor tied to the output voltage. (1) The next step is to calculate the value of C3. The internal compensation has been designed so that when a zero is added from 5 kHz to 10 kHz, the converter will have good transient response with plenty of phase margin for all input and output voltage combinations. 1 FZERO - CF = = 5 kHz o 10 kHz 2S(R2 x Cf) (2) 12 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Feature Description (continued) Lower output voltages will have the zero set closer to 10 kHz, and higher output voltages will usually have the zero set closer to 5 kHz. TI recommends obtaining a Gain and Phase plot for your actual application. See Application and Implementation to obtain examples of working applications and the associated component values. Pole at origin due to internal GM amplifier: FP-ORIGIN (3) Pole due to output load and capacitor: 1 FP- RC = 2S(R Load COUT) (4) This equation only determines the frequency of the pole for perfect current mode control (CMC). That is, it doesn't take into account the additional internal artificial ramp that is added to the current signal for stability reasons. By adding artificial ramp, you begin to move away from CMC to voltage mode control (VMC). The artifact is that the pole due to the output load and output capacitor will actually be slightly higher in frequency than calculated. In this example, it is calculated at 650 Hz, but in reality, it is around 1 kHz. The zero created with capacitor C3 & resistor R2: VO R2 VFB C3 R LOAD R1 Figure 17. Setting External Pole-Zero FZERO - CF = 1 2S(R2 x C3) (5) There is an associated pole with the zero that was created in the above equation. FPOLE - CF = 1 2S((R1 R2) x C3) (6) It is always higher in frequency than the zero. A right-half plane zero (RHPZ) is inherent to all boost converters. One must remember that the gain associated with a right-half plane zero increases at 20 dB per decade, but the phase decreases by 45 per decade. For most applications there is little concern with the RHPZ due to the fact that the frequency at which it shows up is well beyond crossover, and has little to no effect on loop stability. One must be concerned with this condition for large inductor values and high output currents. 2 RHPZERO = (D') RLoad 2S x L (7) There are miscellaneous poles and zeros associated with parasitics internal to the LM2735, external components, and the PCB. They are located well over the crossover frequency, and for simplicity are not discussed. Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 13 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 7.4 Device Functional Modes 7.4.1 Enable Pin and Shutdown Mode The LM2735 has a shutdown mode that is controlled by the Enable pin (EN). When a logic low voltage is applied to EN, the part is in shutdown mode and its quiescent current drops to typically 80 nA. Switch leakage adds up to another 1 A from the input supply. The voltage at this pin should never exceed VIN + 0.3 V. 8 Application and Implementation NOTE Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI's customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality. 8.1 Application Information The device will operate with input voltage in the range of 2.7 V to 5.5 V and provide regulated output voltage. This device is optimized for high-efficiency operation with minimum number of external components. For component selection, see Detailed Design Procedure. 8.2 Typical Applications 8.2.1 LM2735X SOT-23 Design Example 1 L1 4 R3 EN 3 FB 2 GND VIN 5 Vin 12V 1 SW D1 C1 R2 C2 C3 R LOAD R1 Figure 18. LM2735X (1.6 MHz): VIN = 5 V, VOUT = 12 V @ 350 mA 8.2.1.1 Design Requirements The device must be able to operate at any voltage within input voltage range. The load current needs to be defined in order to properly size the inductor, input capacitor, and output capacitor. The inductor must be able to handle full expected load current as well as the peak current generated during load transients and start-up. The inrush current at startup will depend on the output capacitor selection. More details are provided in Detailed Design Procedure. The device has an enable pin (EN) that is used to enable and disable the device. This pin is active high and care should be taken that voltage on this pin does not exceed VIN + 0.3 V. 14 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Typical Applications (continued) 8.2.1.2 Detailed Design Procedure Table 1. Bill of Materials PART ID PART VALUE MANUFACTURER PART NUMBER U1 2.1-A Boost Regulator TI LM2735XMF C1, Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 Comp Capacitor 330 pF TDK C1608X5R1H331K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 15 H 1.5 A Coilcraft MSS5131-153ML R1 10.2 k, 1% Vishay CRCW06031022F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F 8.2.1.2.1 Inductor Selection The duty cycle (D) can be approximated quickly using the ratio of output voltage (VO) to input voltage (VIN): VOUT 1 * 1 = = VIN (c)1 - D Dc (8) Therefore: D= VOUT - VIN VOUT (9) Power losses due to the diode (D1) forward voltage drop, the voltage drop across the internal NMOS switch, the voltage drop across the inductor resistance (RDCR), and switching losses must be included to calculate a more accurate duty cycle (see Calculating Efficiency, and Junction Temperature for a detailed explanation). A more accurate formula for calculating the conversion ratio is: VOUT K = c D VIN where * equals the efficiency of the LM2735 application. (10) The inductor value determines the input ripple current. Lower inductor values decrease the size of the inductor, but increase the input ripple current. An increase in the inductor value will decrease the input ripple current. 'i L I L (t) iL VIN - VOUT VIN L DTS L TS t Figure 19. Inductor Current Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 15 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 2'iL VIN * = DTS (c) L VIN * AiL = x DTS (c) 2L (11) A good design practice is to design the inductor to produce 10% to 30% ripple of maximum load. From the previous equations, the inductor value is then obtained. VIN * x DTS L = (c)2 x 'iL where * 1/TS = FSW = switching frequency (12) Ensure that the minimum current limit (2.1 A) is not exceeded, so the peak current in the inductor must be calculated. The peak current (ILPK ) in the inductor is calculated by: ILpk = IIN + IL (13) ILpk = IOUT / D' + IL (14) or When selecting an inductor, make sure that it is capable of supporting the peak input current without saturating. Inductor saturation will result in a sudden reduction in inductance and prevent the regulator from operating correctly. Because of the speed of the internal current limit, the peak current of the inductor need only be specified for the required maximum input current. For example, if the designed maximum input current is 1.5 A and the peak current is 1.75 A, then the inductor should be specified with a saturation current limit of >1.75 A. There is no need to specify the saturation or peak current of the inductor at the 3-A typical switch current-limit. Because of the operating frequency of the LM2735, ferrite based inductors are preferred to minimize core losses. This presents little restriction since the variety of ferrite-based inductors is huge. Lastly, inductors with lower series resistance (DCR) will provide better operating efficiency. For recommended inductors, see the following design examples. 8.2.1.2.2 Input Capacitor An input capacitor is necessary to ensure that VIN does not drop excessively during switching transients. The primary specifications of the input capacitor are capacitance, voltage, RMS current rating, and ESL (Equivalent Series Inductance). The recommended input capacitance is 10 F to 44 F depending on the application. The capacitor manufacturer specifically states the input voltage rating. Make sure to check any recommended deratings and also verify if there is any significant change in capacitance at the operating input voltage and the operating temperature. The ESL of an input capacitor is usually determined by the effective cross sectional area of the current path. At the operating frequencies of the LM2735, certain capacitors may have an ESL so large that the resulting impedance (2fL) will be higher than that required to provide stable operation. As a result, surface mount capacitors are strongly recommended. Multilayer ceramic capacitors (MLCC) are good choices for both input and output capacitors and have very low ESL. For MLCCs, TI recommends using X7R or X5R dielectrics. Consult capacitor manufacturer datasheet to see how rated capacitance varies over operating conditions. 8.2.1.2.3 Output Capacitor The LM2735 operates at frequencies allowing the use of ceramic output capacitors without compromising transient response. Ceramic capacitors allow higher inductor ripple without significantly increasing output ripple. The output capacitor is selected based upon the desired output ripple and transient response. The initial current of a load transient is provided mainly by the output capacitor. The output impedance will therefore determine the maximum voltage perturbation. The output ripple of the converter is a function of the reactance of the capacitor and its equivalent series resistance (ESR): 16 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 * VOUT x D AVOUT = AIL x R ESR + 2 x F x R x C SW Load OUT (c) (15) When using MLCCs, the ESR is typically so low that the capacitive ripple may dominate. When this occurs, the output ripple will be approximately sinusoidal and 90 phase shifted from the switching action. Given the availability and quality of MLCCs and the expected output voltage of designs using the LM2735, there is really no need to review any other capacitor technologies. Another benefit of ceramic capacitors is their ability to bypass high-frequency noise. A certain amount of switching edge noise will couple through parasitic capacitances in the inductor to the output. A ceramic capacitor will bypass this noise while a tantalum will not. Since the output capacitor is one of the two external components that control the stability of the regulator control loop, most applications will require a minimum at 4.7 F of output capacitance. Like the input capacitor, recommended multilayer ceramic capacitors are X7R or X5R. Again, verify actual capacitance at the desired operating voltage and temperature. 8.2.1.2.4 Setting the Output Voltage The output voltage is set using the following equation where R1 is connected between the FB pin and GND, and R2 is connected between VOUT and the FB pin. VO R2 VFB C3 R LOAD R1 Figure 20. Setting Vout A good value for R1 is 10 k. VOUT * - 1 x R1 R 2 = (c) VREF (16) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 17 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.1.3 Application Curves Vin = 3.3 V Vout = 12 V Vin = 5 V Figure 21. LM2735X Typical Startup Waveform Vout = 12 V Figure 22. LM2735X Typical Startup Waveform 8.2.2 LM2735Y SOT-23 Design Example 2 L1 3 4 FB EN R3 2 GND VIN 12V 1 5 SW Vin D1 C1 R2 C2 C3 R LOAD R1 Figure 23. LM2735Y (520 kHz): VIN = 5 V, VOUT = 12 V at 350 mA 18 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735YMF C1, Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 Comp Capacitor 330 pF TDK C1608X5R1H331K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 33 H 1.5 A Coilcraft DS3316P-333ML R1 10.2 k, 1% Vishay CRCW06031022F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.3 LM2735X WSON Design Example 3 VIN L1 LM2735 R3 C1 C2 D1 1 6 2 5 R2 C5 RLOAD 3 C3 4 C4 R1 Figure 24. LM2735X (1.6 MHz): VIN = 3.3 V, VOUT = 12 V at 350 mA PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735XSD C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M TDK C3216X5R1E106M TDK C1608X5R1H331K C2 Input Capacitor No Load C3 Output Capacitor 10 F, 25 V, X5R C4 Output Capacitor No Load C5 Comp Capacitor 330 pF D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 6.8 H 2 A Coilcraft DO1813H-682ML R1 10.2 k, 1% Vishay CRCW06031022F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 19 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.4 LM2735Y WSON Design Example 4 VIN L1 LM2735 R3 C1 C2 D1 1 6 2 5 R2 C5 RLOAD 3 C3 4 C4 R1 Figure 25. LM2735Y (520 kHz): VIN = 3.3 V, VOUT = 12 V at 350 mA 20 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735YSD C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M TDK C3216X5R1E106M TDK C1608X5R1H331K C2 Input Capacitor No Load C3 Output Capacitor 10 F, 25 V, X5R C4 Output Capacitor No Load C5 Comp Capacitor 330 pF D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 15 H 2 A Coilcraft MSS5131-153ML R1 10.2 k, 1% Vishay CRCW06031022F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.5 LM2735Y MSOP-PowerPAD Design Example 5 VIN L1 D1 R3 LM2735 C1 C2 1 NC NC 8 2 PGND SW 7 3 VIN R2 C5 AGND 6 4 EN R LOAD FB 5 C4 C3 R1 Figure 26. LM2735Y (520 kHz): VIN = 3.3 V, VOUT = 12 V at 350 mA PART ID PART VALUE MANUFACTURER PART NUMBER U1 2.1-A Boost Regulator TI LM2735YMY C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Input Capacitor No Load C3 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C4 Output Capacitor No Load C5 Comp Capacitor 330 pF TDK C1608X5R1H331K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 15 H 1.5 A Coilcraft MSS5131-153ML R1 10.2 k, 1% Vishay CRCW06031022F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 21 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.6 LM2735X SOT-23 Design Example 6 L1 3 4 FB SHDN R3 2 GND VIN 5V 1 5 SW Vin D1 C1 R2 C2 C3 R LOAD R1 Figure 27. LM2735X (1.6 MHz): VIN = 3 V, VOUT = 5 V at 500 mA 22 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735XMF C1, Input Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C2, Output Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C3 Comp Capacitor 1000 pF TDK C1608X5R1H102K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 10 H 1.2 A Coilcraft DO1608C-103ML R1 10.0 k, 1% Vishay CRCW08051002F R2 30.1 k, 1% Vishay CRCW08053012F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback PART NUMBER Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.7 LM2735Y SOT-23 Design Example 7 L1 3 4 R3 FB SHDN 2 GND VIN 5V 1 5 SW Vin D1 C1 R2 C2 C3 R LOAD R1 Figure 28. LM2735Y (520 kHz): VIN = 3 V, VOUT = 5 V at 750 mA PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735YMF C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C3 Comp Capacitor 1000 pF TDK C1608X5R1H102K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 22 H 1.2 A Coilcraft MSS5131-223ML R1 10.0 k, 1% Vishay CRCW08051002F R2 30.1 k, 1% Vishay CRCW08053012F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 PART NUMBER Submit Documentation Feedback 23 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.8 LM2735X SOT-23 Design Example 8 L1 3 4 R3 FB SHDN 2 GND VIN 20V 1 5 SW Vin D1 C1 R2 C2 C3 R LOAD R1 Figure 29. LM2735X (1.6 MHz): VIN = 3.3 V, Vout = 20 V at 100 mA 24 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735XMF C1, Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2, Output Capacitor 4.7 F, 25 V, X5R TDK C3216X5R1E475K C3 Comp Capacitor 470 pF TDK C1608X5R1H471K D1, Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 L1 10 H 1.2 A Coilcraft DO1608C-103ML R1 10.0 k, 1% Vishay CRCW06031002F R2 150 k, 1% Vishay CRCW06031503F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback PART NUMBER Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.9 LM2735Y SOT-23 Design Example 9 L1 3 4 R3 FB SHDN 2 GND VIN 20V 1 5 SW Vin D1 C1 C3 R2 C2 R LOAD R1 Figure 30. LM2735Y (520 kHz): VIN = 3.3 V, VOUT = 20 V at 100 mA PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735YMF C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 Comp Capacitor 470 pF TDK C1608X5R1H471K D1, Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 L1 33 H 1.5 A Coilcraft DS3316P-333ML R1 10.0 k, 1% Vishay CRCW06031002F R2 150.0 k, 1% Vishay CRCW06031503F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 PART NUMBER Submit Documentation Feedback 25 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.10 LM2735X WSON Design Example 10 VIN L1 LM2735 R3 C1 C2 D1 1 6 2 5 R2 C5 RLOAD 3 C3 4 C4 R1 Figure 31. LM2735X (1.6 MHz): VIN = 3.3 V, VOUT = 20 V at 150 mA 26 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735XSD C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C3 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C4 Output Capacitor No Load C5 Comp Capacitor 470 pF TDK C1608X5R1H471K D1, Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 L1 8.2 H 2 A Coilcraft DO1813H-822ML R1 10.0 k, 1% Vishay CRCW06031002F R2 150 k, 1% Vishay CRCW06031503F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.11 LM2735Y WSON Design Example 11 VIN L1 LM2735 R3 C1 C2 D1 1 6 2 5 R2 C5 RLOAD 3 C3 4 C4 R1 Figure 32. LM2735Y (520 kHz): VIN = 3.3 V, VOUT = 20 V at 150 mA PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735YSD C1 Input Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C2 Input Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C3 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C4 Output Capacitor No Load C5 Comp Capacitor 470 pF TDK C1608X5R1H471K D1, Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 L1 22 H 1.5 A Coilcraft DS3316P-223ML R1 10.0 k, 1% Vishay CRCW06031002F R2 150 k, 1% Vishay CRCW06031503F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 27 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.12 LM2735X WSON SEPIC Design Example 12 VIN VO L1 D1 C6 LM2735 C1 C2 1 6 2 5 3 4 L2 R2 R3 C5 C3 C4 R1 Figure 33. LM2735X (1.6 MHz): VIN = 2.7 V - 5 V, VOUT = 3.3 V at 500 mA 28 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735XSD C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M TDK C3216X5R1E106M C2 Input Capacitor No Load C3 Output Capacitor 10 F, 25 V, X5R C4 Output Capacitor No Load PART NUMBER C5 Comp Capacitor 2200 pF TDK C1608X5R1H222K C6 2.2 F 16 V TDK C2012X5R1C225K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 6.8 H Coilcraft DO1608C-682ML L2 6.8 H Coilcraft DO1608C-682ML R1 10.2 k, 1% Vishay CRCW06031002F R2 16.5 k, 1% Vishay CRCW06031652F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.13 LM2735Y MSOP-PowerPAD SEPIC Design Example 13 VIN L1 D1 C6 R3 LM2735 C1 C2 1 NC NC 8 2 PGND SW 7 3 VIN R2 L2 C5 AGND 6 4 EN R LOAD FB 5 C4 C3 R1 Figure 34. LM2735Y (520 kHz): VIN = 2.7 V - 5 V, VOUT = 3.3 V at 500 mA PART ID PART VALUE MANUFACTURER PART NUMBER U1 2.1-A Boost Regulator TI LM2735YMY C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Input Capacitor No Load C3 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C4 Output Capacitor No Load C5 Comp Capacitor 2200 pF TDK C1608X5R1H222K C2012X5R1C225K C6 2.2 F 16 V TDK D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 15 H 1.5 A Coilcraft MSS5131-153ML L2 15 H 1.5 A Coilcraft MSS5131-153ML R1 10.2 k, 1% Vishay CRCW06031002F R2 16.5 k, 1% Vishay CRCW06031652F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 29 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.14 LM2735X SOT-23 LED Design Example 14 L1 R3 4 SHDN Vin 5 Vin 3 FB 2 C2 D1 1 SW C1 R1 R2 DIM - CTRL Figure 35. LM2735X (1.6 MHz): VIN = 2.7 V - 5 V, VOUT = 20 V at 50 mA 30 PART ID PART VALUE MANUFACTURER PART NUMBER U1 2.1-A Boost Regulator TI LM2735XMF C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 4.7 F, 25 V, X5R TDK C3216JB1E475K D1, Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 L1 15 H 1.5 A Coilcraft MSS5131-153ML R1 25.5 , 1% Vishay CRCW080525R5F R2 100 , 1% Vishay CRCW08051000F R3 100 k, 1% Vishay CRCW06031003F Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.15 LM2735Y WSON FlyBack Design Example 15 + 12V D1 R2 Cf T1 V IN C2 R LOAD R1 LM2735 R3 1 C3 6 R LOAD C1 2 5 3 4 D2 - 12V Figure 36. LM2735Y (520 kHz): VIN = 5 V, VOUT = 12 V 150 mA PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI PART NUMBER LM2735YSD C1 Input Capacitor 22 F, 6.3 V, X5R TDK C2012X5R0J226M C2 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M Cf Comp Capacitor 330 pF TDK C1608X5R1H331K D1, D2 Catch Diode 0.4 Vf Schottky 500 mA, 30 VR Vishay MBR0530 R1 10.0 k, 1% Vishay CRCW06031002F R2 86.6 k, 1% Vishay CRCW06038662F R3 100 k, 1% Vishay CRCW06031003F T1 Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 31 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.16 LM2735X SOT-23 LED Design Example 16 VRAIL > 5.5 V Application D1 L1 VPWR R4 4 R3 C4 3 2 5 D2 R2 LM2735 EN C1 C2 1 R1 C3 Figure 37. LM2735X (1.6 MHz): VPWR = 9 V, VOUT = 12 V at 500 mA 32 PART ID PART VALUE MANUFACTURER U1 2.1-A Boost Regulator TI LM2735XMF C1, Input Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C2, Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 VIN Cap 0.1 F, 6.3 V, X5R TDK C2012X5R0J104K C4 Comp Capacitor 1000 pF TDK C1608X5R1H102K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M D2 3.3-V Zener, SOT-23 Diodes Inc BZX84C3V3 L1 6.8 H 2 A Coilcraft DO1813H-682ML R1 10.0 k, 1% Vishay CRCW08051002F R2 86.6 k, 1% Vishay CRCW08058662F R3 100 k, 1% Vishay CRCW06031003F R4 499 , 1% Vishay CRCW06034991F Submit Documentation Feedback PART NUMBER Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 8.2.17 LM2735X SOT-23 LED Design Example 17 Two-Input Voltage Rail Application D1 L1 VPWR LM2735 EN C1 4 R3 R2 3 2 VIN 5 C4 R1 1 C2 C3 Figure 38. LM2735X (1.6 MHz): VPWR = 9 V in = 2.7 V - 5.5 V, VOUT = 12 V at 500 mA PART ID PART VALUE MANUFACTURER PART NUMBER U1 2.1-A Boost Regulator TI LM2735XMF C1, Input Capacitor 10 F, 6.3 V, X5R TDK C2012X5R0J106K C2, Output Capacitor 10 F, 25 V, X5R TDK C3216X5R1E106M C3 VIN Capacitor 0.1 F, 6.3 V, X5R TDK C2012X5R0J104K C4 Comp Capacitor 1000 pF TDK C1608X5R1H102K D1, Catch Diode 0.4 Vf Schottky 1 A, 20 VR ST STPS120M L1 6.8 H 2 A Coilcraft DO1813H-682ML R1 10.0 k, 1% Vishay CRCW08051002F R2 86.6 k, 1% Vishay CRCW08058662F R3 100 k, 1% Vishay CRCW06031003F Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 33 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com 8.2.18 SEPIC Converter VIN VO L1 C6 D1 LM2735 C1 C2 1 6 2 5 3 4 R3 L2 R2 C5 C3 C4 R1 Figure 39. SEPIC Converter Schematic 8.2.18.1 Detailed Design Procedure The LM2735 can easily be converted into a SEPIC converter. A SEPIC converter has the ability to regulate an output voltage that is either larger or smaller in magnitude than the input voltage. Other converters have this ability as well (CUK and Buck-Boost), but usually create an output voltage that is opposite in polarity to the input voltage. This topology is a perfect fit for Lithium Ion battery applications where the input voltage for a single-cell Li-Ion battery will vary from 3 V to 4.5 V and the output voltage is somewhere in-between. Most of the analysis of the LM2735 Boost Converter is applicable to the LM2735 SEPIC Converter. 8.2.18.1.1 SEPIC Design Guide SEPIC Conversion ratio without loss elements: Vo D = D' VIN (17) Therefore: D= VO VO + VIN (18) 8.2.18.1.2 Small Ripple Approximation In a well-designed SEPIC converter, the output voltage, input voltage ripple, and inductor ripple is small in comparison to the DC magnitude. Therefore, it is a safe approximation to assume a DC value for these components. The main objective of the Steady State Analysis is to determine the steady state duty-cycle, voltage and current stresses on all components, and proper values for all components. In a steady-state converter, the net volt-seconds across an inductor after one cycle will equal zero. Also, the charge into a capacitor will equal the charge out of a capacitor in one cycle. Therefore: I L2 D* = ' x I L1 (c)D and IL1 = 34 D * x VO * D' R (c) (c) Submit Documentation Feedback (19) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Substituting IL1 into IL2 VO IL2 = R (20) The average inductor current of L2 is the average output load. VL(t) AREA 1 t (s) AREA 2 DTS TS Figure 40. Inductor Volt-Sec Balance Waveform Applying Charge balance on C1: D' (Vo ) VC1 = D (21) Since there are no DC voltages across either inductor, and capacitor C6 is connected to Vin through L1 at one end, or to ground through L2 on the other end, we can say that VC1 = VIN (22) Therefore: VIN = D' (Vo ) D (23) This verifies the original conversion ratio equation. It is important to remember that the internal switch current is equal to IL1 and IL2. During the D interval. Design the converter so that the minimum specified peak switch current limit (2.1 A) is not exceeded. 8.2.18.1.3 Steady State Analysis With Loss Elements i L1( t ) iC1( t ) vC1( t ) + i D1( t ) vD1( t ) i L 2( t ) i sw VIN i C2( t ) vL2( t ) + - + R L1 vL1( t ) + vC2( t ) vO( t ) - + R on R L2 Using inductor volt-second balance & capacitor charge balance, the following equations are derived: Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 35 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 I L2 www.ti.com VO * =R (c) and IL1 = VO * D * R x D' (c) (c) Vo = VIN (c) (24) * 1 D* D' VD R L2 * D * R ON * D 2 * R L1 * + 1+ + + (c) VO R (c) D' 2 (c) R (c) D' 2 (c) R (c) (25) Therefore: * 1 K= VD R L2 * D * R ON * D 2 * R L1 * + 1+ + + (c) VO R (c) D' 2 (c) R (c) D' 2 (c) R (c) (26) One can see that all variables are known except for the duty cycle (D). A quadratic equation is needed to solve for D. A less accurate method of determining the duty cycle is to assume efficiency, and calculate the duty cycle. VO VIN D= D *xK 1 - D (c) (27) VO * (V x K)+V O (c) IN (28) = Vin Vo Iin Io K 2.7V 3.1V 770 mA 500 mA 75% Vin Vo Iin Io K 3.3V 3.1V 600 mA 500 mA 80% Vin Vo Iin Io K 5V 3.1V 375 mA 500 mA 83% Figure 41. Efficiencies for Typical SEPIC Application 36 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 9 Power Supply Recommendations The LM2735 device is designed to operate from an input voltage supply range from 2.7 V to 5.5 V. This input supply should be able to withstand the maximum input current and maintain a voltage above 2.7 V. In case where input supply is located farther away (more than a few inches) from the device, additional bulk capacitance may be required in addition to the ceramic bypass capacitors. 10 Layout 10.1 Layout Guidelines When planning layout, there are a few things to consider when trying to achieve a clean, regulated output. The most important consideration when completing a boost converter layout is the close coupling of the GND connections of the COUT capacitor and the LM2735 PGND pin. The GND ends should be close to one another and be connected to the GND plane with at least two through-holes. There should be a continuous ground plane on the bottom layer of a two-layer board except under the switching node island. The FB pin is a high impedance node and care should be taken to make the FB trace short to avoid noise pickup and inaccurate regulation. The feedback resistors should be placed as close as possible to the IC, with the AGND of R1 placed as close as possible to the GND (pin 5 for the WSON) of the IC. The VOUT trace to R2 should be routed away from the inductor and any other traces that are switching. High AC currents flow through the VIN, SW and VOUT traces, so they should be as short and wide as possible. However, making the traces wide increases radiated noise, so the designer must make this trade-off. Radiated noise can be decreased by choosing a shielded inductor. The remaining components should also be placed as close as possible to the IC. See Application Note AN-1229 SIMPLE SWITCHER(R) PCB Layout Guidelines (SNVA054) for further considerations and the LM2735 demo board as an example of a 4-layer layout. Below is an example of a good thermal and electrical PCB design. This is very similar to our LM2735 demonstration boards that are obtainable through the TI website. The demonstration board consists of a 2-layer PCB with a common input and output voltage application. Most of the routing is on the top layer, with the bottom layer consisting of a large ground plane. The placement of the external components satisfies the electrical considerations, and the thermal performance has been improved by adding thermal vias and a top layer DogBone. 10.1.1 WSON Package The LM2735 packaged in the 6-pin WSON: Figure 42. Internal WSON Connection For certain high power applications, the PCB land may be modified to a dog bone shape (see Figure 43). Increasing the size of ground plane, and adding thermal vias can reduce the RJA for the application. Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 37 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Layout Guidelines (continued) COPPER PGND 1 6 SW Vin 2 5 AGND EN 3 4 FB COPPER Figure 43. PCB Dog Bone Layout 10.2 Layout Examples CIN PCB VIN PGND L1 FB 4 EN 3 AGND VIN 5 2 PGND SW 6 1 CIN COUT D1 VO Figure 44. Example of Proper PCB Layout 38 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Layout Examples (continued) The layout guidelines described for the LM2735 Boost-Converter are applicable to the SEPIC Converter. Figure 45 shows a proper PCB layout for a SEPIC Converter. CIN PCB VIN PGND L1 FB 4 EN 3 AGND VIN 5 2 PGND SW 6 1 CIN COUT D1 VO C6 L2 Figure 45. SEPIC PCB Layout 10.3 Thermal Considerations When designing for thermal performance, one must consider many variables: * Ambient Temperature: The surrounding maximum air temperature is fairly explanatory. As the temperature increases, the junction temperature will increase. This may not be linear though. As the surrounding air temperature increases, resistances of semiconductors, wires and traces increase. This will decrease the efficiency of the application, and more power will be converted into heat, and will increase the silicon junction temperatures further. * Forced Airflow: Forced air can drastically reduce the device junction temperature. Air flow reduces the hot spots within a design. Warm airflow is often much better than a lower ambient temperature with no airflow. * External Components: Choose components that are efficient, and you can reduce the mutual heating between devices. Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 39 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Thermal Considerations (continued) 10.3.1 Definitions Heat energy is transferred from regions of high temperature to regions of low temperature through three basic mechanisms: radiation, conduction and convection. Radiation Electromagnetic transfer of heat between masses at different temperatures. Conduction Transfer of heat through a solid medium. Convection Transfer of heat through the medium of a fluid; typically air. Conduction & Convection will be the dominant heat transfer mechanism in most applications. RJC Thermal impedance from silicon junction to device case temperature. RJA Thermal impedance from silicon junction to ambient air temperature. CJC Thermal Delay from silicon junction to device case temperature. CCA Thermal Delay from device case to ambient air temperature. RJA & RJC These two symbols represent thermal impedances, and most data sheets contain associated values for these two symbols. The units of measurement are C/Watt. RJAis the sum of smaller thermal impedances (see Figure 46). The capacitors represent delays that are present from the time that power and its associated heat is increased or decreased from steady state in one medium until the time that the heat increase or decrease reaches steady state on the another medium. RTC - A C TC - A TA TC R TJ- CASE C TJ- CASE TJ Internal - P DISS Figure 46. Simplified Thermal Impedance Model The datasheet values for these symbols are given so that one might compare the thermal performance of one package against another. In order to achieve a comparison between packages, all other variables must be held constant in the comparison (PCB size, copper weight, thermal vias, power dissipation, VIN, VOUT, Load Current, and so forth). This does shed light on the package performance, but it would be a mistake to use these values to calculate the actual junction temperature in your application. TJ - TA R TJA = PDissipation (29) We will talk more about calculating the variables of this equation later, and how to eventually calculate a proper junction temperature with relative certainty. For now we need to define the process of calculating the junction temperature and clarify some common misconceptions. 40 Submit Documentation Feedback Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Thermal Considerations (continued) RJA [Variables]: * Input voltage, output voltage, output current, RDSon. * Ambient temperature and air flow. * Internal and external components power dissipation. * Package thermal limitations. * PCB variables (copper weight, thermal vias, layers component placement). It is incorrect to assume that the top case temperature is the proper temperature when calculating RJC value. The RJC value represents the thermal impedance of all six sides of a package, not just the top side. This document will refer to a thermal impedance called RJC. RJC represents a thermal impedance associated with just the top case temperature. This will allow one to calculate the junction temperature with a thermal sensor connected to the top case. 10.3.2 PCB Design With Thermal Performance in Mind The PCB design is a very important step in the thermal design procedure. The LM2735 is available in three package options (5-pin SOT-23, 8-pin MSOP-PowerPAD, and 6-pin WSON). The options are electrically the same, but difference between the packages is size and thermal performance. The WSON and MSOP-PowerPAD have thermal Die Attach Pads (DAP) attached to the bottom of the packages, and are therefore capable of dissipating more heat than the SOT-23 package. It is important that the correct package for the application is chosen. A detailed thermal design procedure has been included in this data sheet. This procedure will help determine which package is correct, and common applications will be analyzed. There is one significant thermal PCB layout design consideration that contradicts a proper electrical PCB layout design consideration. This contradiction is the placement of external components that dissipate heat. The greatest external heat contributor is the external Schottky diode. It would be ideal to be able to separate by distance the LM2735 from the Schottky diode, and thereby reducing the mutual heating effect, however, this will create electrical performance issues. It is important to keep the LM2735, the output capacitor, and Schottky diode physically close to each other (see Figure 44). The electrical design considerations outweigh the thermal considerations. Other factors that influence thermal performance are thermal vias, copper weight, and number of board layers. 10.3.3 LM2735 Thermal Models Heat is dissipated from the LM2735 and other devices. The external loss elements include the Schottky diode, inductor, and loads. All loss elements will mutually increase the heat on the PCB, and therefore increase each other's temperatures. L1 I L (t) D1 VOUT (t) Q1 VIN C1 Figure 47. Thermal Schematic Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 41 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Thermal Considerations (continued) RTCASE-AMB TCASE CTCASE-AMB RTJ-CASE CTJ-CASE INTERNAL PDISS SMALL LARGE PDISS-TOP TAMBIENT PDISS-PCB TJUNCTION RTJ-PCB CTJ-PCB DEVICE EXTERNAL PDISS RTPCB-AMB TPCB CTPCB-AMB PCB Figure 48. Associated Thermal Model 10.3.4 Calculating Efficiency, and Junction Temperature The complete LM2735 DC-DC converter efficiency () can be calculated in the following manner. POUT K= PIN or K= POUT POUT + PLOSS (30) Power loss (PLOSS) is the sum of two types of losses in the converter, switching and conduction. Conduction losses usually dominate at higher output loads, where as switching losses remain relatively fixed and dominate at lower output loads. Losses in the LM2735 device: PLOSS = PCOND + PSW + PQ 42 Submit Documentation Feedback (31) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 Thermal Considerations (continued) Conversion ratio of the boost converter with conduction loss elements inserted: * c * VOUT 1 1 D x VD 1 = R DCR + (D x R DSON) VIN Dc (c) VIN 1+ Dc 2R OUT (c) (32) If the loss elements are reduced to zero, the conversion ratio simplifies to: VOUT 1 = VIN Dc (33) And this is known: K VOUT = VIN Dc (34) Therefore: K= Dc VOUT VIN Dc x VD * 1 VIN = + (D x R DSON) R 1 + DCR Dc 2R OUT (c) (35) Calculations for determining the most significant power losses are discussed below. Other losses totaling less than 2% are not discussed. A simple efficiency calculation that takes into account the conduction losses is shown below: Dc x VD * 1 V IN K| R DCR + (D x R DSON) 1+ Dc 2R OUT (c) (36) The diode, NMOS switch, and inductor DCR losses are included in this calculation. Setting any loss element to zero will simplify the equation. VD is the forward voltage drop across the Schottky diode. It can be obtained from the manufacturer's Electrical Characteristics section of the data sheet. The conduction losses in the diode are calculated as follows: PDIODE = VD x IO (37) Depending on the duty cycle, this can be the single most significant power loss in the circuit. Care should be taken to choose a diode that has a low forward voltage drop. Another concern with diode selection is reverse leakage current. Depending on the ambient temperature and the reverse voltage across the diode, the current being drawn from the output to the NMOS switch during time D could be significant, this may increase losses internal to the LM2735 and reduce the overall efficiency of the application. Refer to Schottky diode manufacturer's data sheets for reverse leakage specifications, and typical applications within this data sheet for diode selections. Another significant external power loss is the conduction loss in the input inductor. The power loss within the inductor can be simplified to: PIND = IIN2RDCR (38) I 2 R * PIND = O DCR D' (c) (39) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 43 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Thermal Considerations (continued) The LM2735 conduction loss is mainly associated with the internal NFET: PCOND-NFET = I2SW-rms x RDSON x D (40) 'i I I sw(t) t Figure 49. LM2735 Switch Current 'i IIND Isw-rms = IIND D x 1 + 1 3 2 | IIND D PIND = IIN2 x RIND-DCR (small ripple approximation) PCOND-NFET = IIN2 x RDSON x D (41) (42) 2 I * PCOND - NFET = O x RDSON x D (c) D' (43) The value for should be equal to the resistance at the junction temperature you wish to analyze. As an example, at 125C and VIN = 5 V, RDSON = 250 m (see Typical Characteristics for value). Switching losses are also associated with the internal NMOS switch. They occur during the switch on and off transition periods, where voltages and currents overlap resulting in power loss. The simplest means to determine this loss is to empirically measuring the rise and fall times (10% to 90%) of the switch at the switch node: PSWR = 1/2(VOUT x IIN x FSW x TRISE) PSWF = 1/2(VOUT x IIN x FSW x TFALL) PSW = PSWR + PSWF (44) (45) (46) Table 2. Typical Switch-Node Rise and Fall Times VIN VOUT TRISE TFALL 3V 5V 6 nS 4 nS 5V 12 V 6 nS 5 nS 3V 12 V 7 nS 5 nS 5V 18 V 7 nS 5 nS Quiescent Power Losses: IQ is the quiescent operating current, and is typically around 4 mA. PQ = IQ x VIN 44 Submit Documentation Feedback (47) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 LM2735, LM2735-Q1 www.ti.com SNVS485G - JUNE 2007 - REVISED AUGUST 2015 10.3.4.1 Example Efficiency Calculation Table 3. Operating Conditions PARAMETER VALUE VIN 5V VOUT 12 V IOUT 500 mA VD 0.4 V FSW 1.60 MHz IQ 4 mA TRISE 6 nS TFALL 5 nS RDSon 250 m RDCR 50 m D 0.64 IIN 1.4 A PCOND + PSW + PDIODE + PIND + PQ = PLOSS (48) Quiescent Power Losses: PQ = IQ x VIN = 20 mW (49) Switching Power Losses: PSWR = 1/2(VOUT x IIN x FSW x TRISE) 6 ns 80 mW PSWF = 1/2(VOUT x IIN x FSW x TFALL) 5 ns 70 mW PSW = PSWR + PSWF = 150 mW (50) (51) (52) Internal NFET Power Losses: RDSON = 250 m PCONDUCTION = IIN2 x D x RDSON x 305 mW (53) (54) Diode Losses: VD = 0.45 V PDIODE = VD x IIN(1-D) = 236 mW (55) (56) Inductor Power Losses: RDCR = 75 m PIND = IIN2 x RDCR = 145 mW (57) (58) Copyright (c) 2007-2015, Texas Instruments Incorporated Product Folder Links: LM2735 LM2735-Q1 Submit Documentation Feedback 45 LM2735, LM2735-Q1 SNVS485G - JUNE 2007 - REVISED AUGUST 2015 www.ti.com Total Power Losses are: Table 4. Power Loss Tabulation PARAMETER VALUE VIN 5V PARAMETER VOUT 12 V IOUT 500 mA POUT 6W VD 0.4 V PDIODE 236 mW FSW 1.6 MHz TRISE 6 nS PSWR 80 mW TFALL 5 nS PSWF 70 mW IQ 4 mA PQ 20 mW RDSon 250 m PCOND 305 mW RDCR 75 m PIND 145 mW D 0.623 86% PLOSS 856 mW PINTERNAL = PCOND + PSW = 475 mW VALUE (59) 10.3.5 Calculating RJA and RJC R TJA = TJ - TA PDissipation and R