340KHz, 2A, Asynchronous Step-Down Regulator

Similar documents
340KHz, 2A, Asynchronous Step-Down Regulator

340KHz, 3A, Asynchronous Step-Down Regulator

1.5MHz, 3A Synchronous Step-Down Regulator

1.5MHz, 2A Synchronous Step-Down Regulator

5V, 3A, 1.5MHz Buck Constant Current Switching Regulator for White LED

28V, 3A Buck Constant Current Switching Regulator for White LED

1.5MHz, 800mA Synchronous Step-Down Regulator

1.5MHz, 1A Synchronous Step-Down Regulator

1.5MHz, 600mA Synchronous Step-Down Regulator

28V, 3A Buck Constant Current Switching Regulator for White LED

2A, 23V, 380KHz Step-Down Converter

Dual 1.5MHz, 1A Synchronous Step-Down Regulator

2A, 23V, 380KHz Step-Down Converter

FP kHz 7A High Efficiency Synchronous PWM Boost Converter

3A, 23V, 380KHz Step-Down Converter

2A, 23V, 340KHz Synchronous Step-Down Converter

20V, 2A Buck Switching Regulator

Low-Noise 4.5A Step-Up Current Mode PWM Converter

FP6276B 500kHz 6A High Efficiency Synchronous PWM Boost Converter

1.5MHz, 1.5A Synchronous Step-Down Regulator

Switching Boost Regulator

FP A Current Mode Non-Synchronous PWM Boost Converter

Constant Current Switching Regulator for White LED

1.2A, 23V, 1.4MHz Step-Down Converter

10A Current Mode Non-Synchronous PWM Boost Converter

Non-Synchronous PWM Boost Controller

Non-Synchronous PWM Boost Controller for LED Driver

3A, 36V, Step-Down Converter

Dual 1.5MHz, 1A Synchronous Step-Down Regulator

Dual Channel PWM Controller with SCP / DTC Function

Low-Noise Step-Up Current Mode PWM Converter

AIC2858 F. 3A 23V Synchronous Step-Down Converter

EUP V/12V Synchronous Buck PWM Controller DESCRIPTION FEATURES APPLICATIONS. Typical Application Circuit. 1

1.0MHz,24V/2.0A High Performance, Boost Converter

Non-Synchronous PWM Boost Controller

700mA LED Driver with Internal Switch

Low-Noise Step-Up Current Mode PWM Converter

RT A, 2MHz, Synchronous Step-Down Converter. General Description. Features. Applications. Ordering Information. Pin Configurations

idesyn id8802 2A, 23V, Synchronous Step-Down DC/DC

TFT-LCD DC/DC Converter with Integrated Backlight LED Driver

EUP A, Synchronous Step-Down Converter DESCRIPTION FEATURES APPLICATIONS. Typical Application Circuit

UNISONIC TECHNOLOGIES CO., LTD

23V 3A Step-Down DC/DC Converter

The ASD5001 is available in SOT23-5 package, and it is rated for -40 to +85 C temperature range.

1.5 MHz, 600mA Synchronous Step-Down Converter

MP2494 2A, 55V, 100kHz Step-Down Converter

RT V DC-DC Boost Converter. Features. General Description. Applications. Ordering Information. Marking Information

EM5812/A. 12A 5V/12V Step-Down Converter. Applications. General Description. Pin Configuration. Ordering Information. Typical Application Circuit

Techcode. 1.6A 32V Synchronous Rectified Step-Down Converte TD1529. General Description. Features. Applications. Package Types DATASHEET

Dual Operational Amplifier and Reference Regulator

LSP5504. PWM Control 2A Step-Down Converter. Applications. General Description. Features LSP5504. Typical Application Circuit

RT8288A. 4A, 21V 500kHz Synchronous Step-Down Converter. General Description. Features. Applications. Ordering Information. Pin Configurations

A7121A. AiT Semiconductor Inc. APPLICATION ORDERING INFORMATION TYPICAL APPLICATION

RT A, 2MHz, Synchronous Step-Down Converter. Features. General Description. Applications. Ordering Information. Marking Information

1.5MHz, 1.5A Step-Down Converter

OCP2030 SWITCHING BUCK REGULATOR

LX MHz, 1A Synchronous Buck Converter. Description. Features. Applications LX7188

DT V 1A Output 400KHz Boost DC-DC Converter FEATURES GENERAL DESCRIPTION APPLICATIONS ORDER INFORMATION

Preliminary. Synchronous Buck PWM DC-DC Controller FP6329/A. Features. Description. Applications. Ordering Information.

RT8086B. 3.5A, 1.2MHz, Synchronous Step-Down Converter. General Description. Features. Ordering Information RT8086B. Applications. Marking Information

COTAG. YF KHz, 4A / 23V Step-Down Converter YF1205

RT9296. Synchronous Boost Converter with LDO Controller. General Description. Features. Applications. Ordering Information RT9296(- )

FP V, 3.1A, 550KHz High Efficiency Low Ripple Synchronous Step-Up Converter. Description. Features. Applications.

eorex EP MHz, 600mA Synchronous Step-down Converter

23V, 3A, 340KHz Synchronous Step-Down DC/DC Converter

AME. High Efficiency 500KHz Step-Up Converter AME5125. n General Description. n Features. n Function Diagram. n Applications. n Typical Application

RT8477. High Voltage High Current LED Driver. Features. General Description. Applications. Ordering Information RT8477. Pin Configurations (TOP VIEW)

WD3119 WD3119. High Efficiency, 40V Step-Up White LED Driver. Descriptions. Features. Applications. Order information 3119 FCYW 3119 YYWW

FAN2013 2A Low-Voltage, Current-Mode Synchronous PWM Buck Regulator

EM A Low Dropout LDO. General Description. Applications. Pin Configuration. Ordering Information. Features. Typical Application Circuit

LX7157B 3V Input, High Frequency, 3A Step-Down Converter Production Datasheet

RT2805A. 5A, 36V, 500kHz Current Mode Asynchronous Step-Down Converter. General Description. Features. Applications. Ordering Information

1.5MHz, 1.5A, Step-down DC-DC Converter. Features

AME. 40V CC/CV Buck Converter AME5244. n General Description. n Typical Application. n Features. n Functional Block Diagram.

ACE7215C 1.5A 1.5MHz Synchronous Buck Converter

MP A, 50V, 1.2MHz Step-Down Converter in a TSOT23-6

1A 1.5MHz PFM/PWM Synchronous Step-Down Converter. January 2014 Rev FEATURES. Fig. 1: XRP6658 Application Diagram

A7221 DC-DC CONVERTER/ BUCK (STEP-DOWN) HIGH EFFICIENCY FAST RESPONSE, 2A, 16V INPUT SYNCHRONOUS STEP-DOWN CONVERTER

340KHz, 36V/2.5A Step-down Converter With Soft-Start

ESMT Preliminary EML3273

Asynchronous Boost Controller

AME, Inc. PWM Control 2A Buck Converter AME5106. Applications. General Description. Features

Datasheet. 4A 240KHZ 23V PWM Buck DC/DC Converter. Features

REV1.0 - AUG 2012 RELEASED

TS3410 1A / 1.4MHz Synchronous Buck Converter

AIC1340 High Performance, Triple-Output, Auto- Tracking Combo Controller

RT CH Power Management IC. General Description. Features. Applications. Pin Configurations

AT V 5A Synchronous Buck Converter

EUP2511. HQI Boost Converter With 2.1A Switch In Tiny SOT-23 Package FEATURES DESCRIPTION APPLICATIONS. Typical Application Circuit

A7108. AiT Semiconductor Inc. APPLICATION ORDERING INFORMATION TYPICAL APPLICATION

AME. 1.2A, 1.5MHz Synchronous Step-Down Converter AME5259 A. n General Description. n Applications. n Typical Application.

Rail Current Measurement IC

RT8509A. 4.5A Step-Up DC/DC Converter. General Description. Features. Applications. Ordering Information. Marking Information

LD /01/2013. Boost Controller for LED Backlight. General Description. Features. Applications. Typical Application REV: 00

DIO6305 High-Efficiency 1.2MHz, 1.1A Synchronous Step-Up Converter

HM2259D. 2A, 4.5V-20V Input,1MHz Synchronous Step-Down Converter. General Description. Features. Applications. Package. Typical Application Circuit

EUP A,40V,200KHz Step-Down Converter

AT MHz 2A SOT-26 Step Up DC-DC Converter

RT8078A. 4A, 1MHz, Synchronous Step-Down Converter. General Description. Features. Applications

EUP A, Synchronous Step-Down Converter DESCRIPTION FEATURES APPLICATIONS. Typical Application Circuit

Transcription:

340KHz, 2A, Asynchronous Step-Down Regulator FP6115 General Description The FP6115 is a buck switching regulator for wide operating voltage application fields. The FP6115 includes a high current P-MOSFET, a high precision reference (0.8V) for comparing output voltage with a feedback amplifier, an internal soft start timer and dead-time controller. The oscillator is for controlling the maximum duty cycle and PWM frequency. Features Precision Feedback Reference Voltage: 0.8V (2%) Wide Supply Voltage Operating Range: 3.6 to 23V Low Current Consumption: 3mA Internal Fixed Oscillator Frequency: 340KHz (Typ.) Internal Soft-Start Function (SS) Built-In P-MOSFET for 2A Output Loading Over Current Protection Package: SOP-8L Typical Application Circuit 1/14

Function Block Diagram Pin Descriptions SOP-8L FB 1 TOP View 8 GND Name No. I / O Description FB 1 I Error Amplifier Inverting Input EN 2 I Enable Control OCSET 3 I Set Switch Output Over Current EN OCSET 2 3 7 6 GND LX V CC 4 P IC Power Supply (PMOS Source) LX 5 O PMOS High Current Output LX 6 O PMOS High Current Output V CC 4 5 LX GND 7 P IC Ground GND 8 P IC Ground 2/14

Marking Information FP6115 9Fa-86L Halogen Free Lot Number Internal ID Per-Half Month Year Halogen Free: Halogen free product indicator Lot Number: Wafer lot number s last two digits For Example: 132386TB 86 Internal ID: Internal Identification Code Per-Half Month: Production period indicated in half month time unit For Example: January A (Front Half Month), B (Last Half Month) February C (Front Half Month), D (Last Half Month) Year: Production year s last digit 3/14

Ordering Information Part Number Operating Temperature Package MOQ Description FP6115DR-G1-25 C ~ +85 C SOP-8L 2500 EA Tape & Ree l Absolute Maximum Ratings Parameter Symbol Conditions Min. Typ. Max. Unit Power Supply Voltage V CC 23 V Output Source Current 3.5 A Error Amplifier Inverting Input -0.3 1.2 V Allowable Power Dissipation P D SOP-8L T A +25 C 650 mw Thermal Resistance Junction to Ambient θ JA +110 C / W Operating Temperature -25 +85 C ESD Susceptibility HBM (Human Body Mode) 2 KV MM (Machine Mode) 200 V Storage Temperature T S SOP-8L -55 +125 C SOP-8L Lead Temperature (soldering, 10 sec) +260 C IR Re-flow Soldering Curve 4/14

Recommended Operating Conditions Parameter Symbol Conditions Min. Typ. Max. Unit Supply Voltage V CC 3.6 23 V Operating Temperature -25 85 C DC Electrical Characteristics (V CC =6V,T A = 25 C, unless otherwise noted) Reference Parameter Symbol Conditions Min. Typ. Max. Unit Feedback Voltage V REF 0.784 0.8 0.816 V Input Regulation V REF / V CC=3.6 V to 23 V 1 2 % Feedback Voltage Change with Temperature Oscillator Section V REF V REF / T A=- -25 C to +85 C 1 2 % V REF Oscillation Frequency f Measured from LX pin waveform 340 KHz Short Circuit or Over Current Measured from LX pin f Oscillation Frequency SC waveform 50 KHz Frequency Change with Voltage f / V V CC=3.6V to 23V 5 % Frequency Change with Temperature f / T T A = -25 C to +85 C 5 % Idle Period Adjustment Section Maximum Duty Cycle T DUTY V FB =0.2V 80 % Output Section PMOS Switch Current I LX -2 A PMOS On Resistance R DS (ON) Thermal Shutdown Section VCC=4.5V 70 95 mω V CC=10V 50 60 mω Thermal Shutdown Temperature +150 C Over Current Protection Section OCSET Bias Current I OCSET 40 µa Total Device Section EN Pin Input Current I EN V EN=2.5V 20 µa EN Pin On Threshold V UPPER EN pin upper 1.1 V EN Pin Off Threshold V LOW EN pin low 0.85 V EN Pin Hysteresis V HYS 200 250 mv Supply Shutdown Current I SD V EN=0V 2 10 µa Supply Average current I AVE 3 6 ma 5/14

Typical Operating Characteristics VOUT(V) 3.55 3.53 3.51 3.49 3.47 3.45 3.43 3.41 3.39 3.37 3.35 Load Regulation V IN=12V 0 0.5 1 1.5 2 I OUT (A) Oscillator Frequency(kHz) Oscillator Frequency vs. V IN V OUT=3.3V I 360 OUT=200mA 358 356 354 352 350 348 346 344 342 340 0 5 10 15 20 V IN(V) 3.438 Line Regulation I OUT=200mA 4 Current Limit vs. Temperature VOUT (V) 3.436 3.434 3.432 3.43 3.428 3.426 3.424 Current Limit (A) 3.8 3.6 3.4 3.2 Rset=3k 3.422 3.42 3.418 0 5 10 15 20 V IN (V) 3 2.8-40 -20 0 20 40 60 80 100 Temperature ( ) Supply Current (ma) 3.5 3.45 3.4 3.35 3.3 3.25 3.2 Supply Current vs. V IN 0 5 10 15 20 V IN (V) Current Limit (A) 3.6 3.5 3.4 3.3 3.2 3.1 3 2.9 2.8 Rset=3k Current Limit vs. V IN 0 5 10 15 20 V IN (V) Supply Current (ma) 3.4 3.38 3.36 3.34 3.32 3.3 3.28 3.26 3.24 3.22 3.2 Supply Current vs. Temperature -40-20 0 20 40 60 80 100 Temperature ( ) Current Limit (A) Ocset resistance vs. Current Limit 4 3.5 3 2.5 2 1.5 1 1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 Ocset Resistance (kω) 6/14

Efficiency Efficiecncy (V IN=12V,L=22uH) 100 Efficiency Efficiecncy (V IN=5V,L=22uH) 90 90 Efficiency (%) 80 70 60 VOUT=3.3V VOUT=5V Efficiency (%) 80 70 60 VOUT=3.3V VOUT=2.5V 50 0 0.5 1 1.5 2 I OUT (A) 50 0 0.5 1 1.5 2 I OUT (A) Output Ripple (V IN=12V,V OUT=3.3V,I OUT= 2A) Transient Response (V IN=12V,V OUT=3.3V,I OUT=0.2A to 2A) Ch1 LX Ch2 V OUT EN on Test (V IN=12V,V OUT=3.3V,Iout=2A) Ch3 V OUT Ch4 I LX Power on Test (V IN=12V,V OUT=3.3V,I OUT=2A) Ch1 EN Ch2 LX Ch3 V OUT Ch4 I LX Ch1 V IN Ch2 LX Ch3 V OUT Ch4 I LX 7/14

Function Description Voltage Reference A 2.5V reference regulator supplies FP6115 internal circuits and uses a resistive divider to provide 0.8V precision reference voltage on the non-inverting terminal of error amplifier. Error Amplifier The error amplifier compares a sample of the DC-DC converter output voltage to the 0.8V (V REF ) reference and generates an error signal for the PWM comparator. Output voltage of the DC-DC converter is setting by the resistor divider with following expression (see Fig. 1) R 2 V OUT = 1 + V R 1 REF V OUT R 2 Error Amplifier 1 36K R 1 0.8V FP6115 Figure 1. Error Amplifier with Feedback Resistance Divider The recommended resistor value is summarized below: V OUT (V) R 1 (kω) R 2 (kω) 1.8 2.4k 3k 2.5 3.2k 6.8k 3.3 1.5k 4.7k 5 2k 10.5k 8/14

Oscillator The fixed frequency is generated by an internal RC oscillator. Its typical values is 340KHz in normal operation and 50KHz in short circuit condition. Thermal Protection When a heavy loading draws current from the regulator, the chip temperature will rise. Once the junction temperature exceeds 150, FP6115 thermal protection function will be triggered and the LX output will be turned off. When junction temperature is lower, FP6115 starts again and enable LX pin output. Over Current Protection The FP6115 uses cycle-by-cycle current limit to protect the internal power switch. During each switching cycle, a current limit comparator detects if the power switch current exceeds the external setting current or not. Once over current occurs, chip will decrease the oscillator frequency to prevent from thermal issue. The current limit threshold is setting by external resistor (R 3 ) which is connecting from V CC to OCSET pin. An internal 40µA current sink which draws current from the resistor sets the voltage at pin OCSET. Please refer to the following formula for setting the current limit value: I OCP I = OCSET R 35mΩ 3 Here, 35mΩ is internal sense resistance. Example: 40µ A 2.49k I OCP = = 2.85A 35mΩ 9/14

Application Information Input Capacitor Selection The input capacitor must be connected to the V CC pin and GND pin of the FP6115 to maintain steady input voltage and filter out the pulsing input current. The voltage rating of input capacitor must be greater than maximum input voltage plus ripple voltage. In switch mode, the input current is discontinuous in a buck converter. The source current of the high-side MOSFET is a square wave. To prevent large voltage transients, a low ESR input capacitor sized for the maximum RMS current must be used. The RMS value of input capacitor current can be calculated by: V V 1 V = O O RMS IO MAX VIN IN I It can be seen that when V O is half of V IN, C IN is under the worst current stress. The worst current stress on C IN is I O_MAX / 2. Inductor Selection The value of the inductor is selected based on the desired ripple current. Large inductance gives low inductor ripple current and small inductance result in high ripple current. However, the larger value inductor usually has a larger physical size, higher series resistance, and lower saturation current. On the experience, the value is to allow the peak-to-peak ripple current in the inductor to be 10%~20% maximum load current. The inductance value can be calculated by: (VIN V L = f I L O ) V V O IN = f (V IN V O V O [ 2 (10% ~ 20%)IO] VIN ) The inductor ripple current can be calculated by: I L VO V = 1 f L V O IN Choose an inductor that does not saturate under the worst-case load conditions, which is the load current plus half the peak-to-peak inductor ripple current, even at the highest operating temperature. The peak inductor current is: I L _PEAK = I O I + 2 L 10/14

The inductors in different shape and style are available from manufacturers. Shielded inductors are small and radiate less EMI issue. But they cost more than unshielded inductors. The choice depends on EMI requirement, price and size. Inductor Value (µh) Dimensions(mm) Component Supplier Model 10 10.3 10.3 4.0 FENG-JUI TPRH10D40-10R 10 10.1 10.1 3.0 Sumida CDRH104R 15 10.3 10.3 4.0 FENG-JUI TPRH10D40-15R Output Capacitor Selection The output capacitor is required to maintain the DC output voltage. Low ESR capacitors are preferred to keep the output voltage ripple low. In a buck converter circuit, output ripple voltage is determined by inductor value, switching frequency, output capacitor value and ESR. The output ripple is determined by: V O = I L ESR C OUT 1 + 8 f C OUT Where f = operating frequency, C OUT = output capacitance and I L = ripple current in the inductor. For a fixed output voltage, the output ripple is highest at maximum input voltage since I L increases with input voltage. Using Ceramic Input and Output Capacitors Care must be taken when ceramic capacitors are used at the input and the output. When a ceramic capacitor is used at the input and the power is supplied by a wall adapter through long wires, a load step at the output can induce ringing at the input, V IN. In best condition, this ringing can couple to the output and be mistaken as loop instability. In worst condition, a sudden inrush of current through the long wires can potentially generate a voltage spike at V IN, which may large enough to damage the part. When choosing the input and output ceramic capacitors, choose the one with X5R or X7R dielectric formulations. These dielectrics have the best temperature and voltage characteristics of all the ceramics for a given value and size. PC Board Layout Checklist 1. The power traces, consisting of the GND trace, the LX trace and the V IN trace should be kept short, direct and wide. 2. Place C IN near V CC pin as closely as possible to maintain input voltage steady and filter out the pulsing input current. 3. The resistive divider R 1 and R 2 must be connected to FB pin directly as closely as possible. 11/14

4. FB is a sensitive node. Please keep it away from switching node, LX. A good approach is to route the feedback trace on another layer and to have a ground plane between the top layer and the layer on which the feedback trace is routed. This reduces EMI radiation on to the DC-DC converter s own voltage feedback trace. 5. Keep the GND plates of C IN and C OUT as close as possible. Then connect this to the ground plane (if one is used) with several vias. This reduces ground plane noise by preventing the switching currents from circulating through the ground plane. It also reduces ground bounce at the FP6115 GND pin by giving it a low impedance ground connection. Suggested Layout 12/14

Typical Application FP6115 Basic DC-DC Regulator Circuits For example: The V IN power supply is 12V and the V OUT is designed for 5.0V / 2A solution. The output voltage formula is: R 2 10.5KΩ VOUT = 1 + VREF = 1+ 0.8V = 5.0V R 1 2KΩ 13/14

Package Outline SOP-8L UNIT: mm Symbols Min. (mm) Max. (mm) A 1.346 1.752 A1 0.101 0.254 A2 1.498 D 4.800 4.978 E 3.810 3.987 H 5.791 6.197 L 0.406 1.270 θ 0 8 Note: 1. Package dimensions are in compliance with JEDEC Outline: MS-012 AA. 2. Dimension D does not include molding flash, protrusions gate burrs. 3. Dimension E does not include inter-lead flash, or protrusions. 14/14