General Description The SmartSwitch is a member of AnalogicTech s Application Specific Power MOSFET (ASPM ) product family. The is a dual P-channel MOSFET power switch designed for high-side load-switching applications. Each MOSFET has a typical R DS(ON) of mω, allowing increased load switch current handling capacity with a low forward voltage drop. The device is available in three different versions with flexible turn-on and turn-off characteristics from very fast to slew-rate limited. The standard 8A (-) version has a slew-rate limited turn-on load switch. The (-) version features fast turn-on capability, typically less than 5ns turn-on and μs turn-off times. The (-) variation offers a shutdown load discharge circuit to rapidly turn off a load circuit when the switch is disabled. An additional feature is a slew-rate selector pin which can switch between fast and slow slew rate. All the load switch versions are designed to operate from.5v up to.5v, making them ideal for both V and 5V systems. Input logic levels are TTL and.5v to 5V CMOS compatible. The quiescent supply current is a very low μa. The is available in the Pb-free, low profile.x.mm FTDFN-8 package and the FSC7JW-8 package and is specified over the - C to 85 C temperature range. Features V IN Range:.5V to.5v Low R DS(ON) mω Typical @ 5V mω Typical @.5V Slew Rate Turn-On Time Options ms.5μs μs Fast Shutdown Load Discharge Option Low Quiescent Current Typically μa TTL/CMOS Input Logic Level Temperature Range - C to 85 C FTDFN-8 and FSC7JW-8 Packages Applications Cellular Telephones Digital Still Cameras Hotswap Supplies Notebook Computers PDA Phones PDAs PMPs Smartphones Typical Application INA INA OUTA OUTA OUTB OUTB ON/OFF C μf C μf ON/OFF FAST/SLOW FAST GND C.μF C.μF 8A.9.7.. www.analogictech.com
Pin Descriptions Pin # FTDFN-8 FSC7JW-8 Symbol Function 8 INA This is the pin to the P-channel MOSFET source for Switch A. Bypass to ground through a μf capacitor. INA is independent of 7 Active-High Enable Input A. A logic low turns the switch off and the device consumes less than μa of current. Logic high resumes normal operation. Active-High Enable Input B. A logic low turns the switch off and the device consumes less than μa of current. Logic high resumes normal operation. 5 This is the pin to the P-channel MOSFET source for Switch B. Bypass to ground through a μf capacitor. is independent of INA. 5 OUTB This is the pin to the P-channel MOSFET drain connection. Bypass to ground through a.μf capacitor. GND Ground connection 7 FAST Active-high input Switches between FAST (Logic H) and SLOW (Logic L) Slew rate 8 OUTA This is the pin to the P-channel MOSFET drain connection. Bypass to ground through a.μf capacitor. Pin Configuration FTDFN-8 (Top View) FSC7JW-8 (Top View) INA 8 7 5 OUTA FAST GND OUTB OUTA FAST GND OUTB 8 7 5 INA www.analogictech.com 8A.9.7..
Selector Guide Part Number FAST (H) Slew Rate (Typ) SLOW (L) Active Pull-Down Enable - ms NO Active High -.5μs NO Active High - μs ms YES Active High Absolute Maximum Ratings Symbol Description Value Units V IN IN to GND -. to 7 V V EN, FAST EN, FAST to GND -. to 7 V V OUT OUT to GND -. to V IN +. V I MAX Maximum Continuous Switch Current A I DM Maximum Pulsed Current (Duty Cycle %) 5.5 A T J Operating Junction Temperature Range - to 5 C T LEAD Maximum Soldering Temperature (at leads) C V ESD ESD Rating HBM V Thermal Characteristics Symbol Description Value Units θ JA Thermal Resistance 7 C/W P D Maximum Power Dissipation.78 W. Parts not available in stock, but can be ordered.. Stresses above those listed in Absolute Maximum Ratings may cause permanent damage to the device. Functional operation at conditions other than the operating conditions specified is not implied. Only one Absolute Maximum Rating should be applied at any one time.. Human body model is a pf capacitor discharged through a.5kω resistor into each pin.. Mounted on a demo board in still 5 C air. 8A.9.7.. www.analogictech.com
Electrical Characteristics V IN = 5V, T A = - to 85 C unless otherwise noted. Typical values are at T A = 5 C. Per channel. Symbol Description Conditions Min Typ Max Units All Versions V IN Operation Voltage.5.5 V I Q Quiescent Current ON/OFF = ACTIVE, FAST = V IN, I OUT =. μa I Q(OFF) Off Supply Current ON/OFF = Inactive, OUT = Open. μa I SD(OFF) Off Switch Current ON/OFF = GND, V OUT =. μa V IN =.5V 5 V IN = 5V R DS(ON) On-Resistance A or B V IN =.V 5 V IN =.V 7 mω V IN =.8V V IN =.5V 8 TCR RDS On Resistance Temperature Coefficient 8 ppm/ C V IL ON/OFF Input Logic Low Voltage V IN =.5V. V V IH ON/OFF Input Logic High Voltage V IN = 5V. V I SINK ON/OFF Input Leakage V ON/OFF = 5.5V. μa - T D(ON) Output Turn-On Delay Time V IN = 5V, R LOAD =Ω, T A =5 C μs T ON Turn-On Rise Time V IN = 5V, R LOAD =Ω, T A =5 C 5 μs T D(OFF) Output Turn-OFF Delay Time V IN = 5V, R LOAD =Ω, T A =5 C. μs - T D(ON) Output Turn-On Delay Time V IN = 5V, R LOAD =Ω, T A =5 C.5 μs T ON Turn-On Rise Time V IN = 5V, R LOAD =Ω, T A =5 C.5. μs T D(OFF) Output Turn-OFF Delay Time V IN = 5V, R LOAD =Ω, T A =5 C. μs - T D(ON) Output Turn-On Delay Time V IN = 5V, R LOAD =Ω, T A =5 C μs T ON Turn-On Rise Time V IN = 5V, R LOAD =Ω, FAST = 5V, T A =5 C 5 μs T ON Turn-On Rise Time V IN = 5V, R LOAD =Ω, FAST = V, T A =5 C 5 μs T D(OFF) Output Turn-OFF Delay Time V IN = 5V, R LOAD =Ω, T A =5 C. μs R PD Output Pull-Down Resistance During OFF ON/OFF = Inactive, T A =5 C 5 5 Ω. The is guaranteed to meet performance specifications over the - C to +85 C operating temperature range and is assured by design, characterization, and correlation with statistical process controls.. Contact factory for other turn on and delay options. www.analogictech.com 8A.9.7..
Typical Characteristics V IN = 5V, T A = 5 C unless otherwise noted. Quiescent Current vs. Temperature (No Load; Single Switch) Quiescent Current vs. Input Voltage (No Load; Single Switch) Quiescent Current (µa) 8 V IN = 5V V IN = V Quiescent Current (µa) 8 - -5 5 85 5 Temperature ( C) Input Voltage (V) Off Supply Current vs. Temperature (No Load; EN = GND; VIN = 5V) Typical ON/OFF Threshold vs. Input Voltage. Off Supply Current (µa).9.8.7..5.... - -5 5 85 ON/OFF Threshold (V).. V IH.9 V IL.8.7..5.5.5.5 5 5.5 Temperature ( C) Input Voltage (V) On-Resistance vs. Temperature On-Resistance vs. Input Voltage On-Resistance (mω) 9 8 V IN = V 7 5 V IN = 5V - -5 5 85 On-Resistance (mω) 8 I SW = A 8 I SW = ma.5.5.5.5 5.5.5 Temperature ( C) Input Voltage (V) 8A.9.7.. www.analogictech.com 5
Typical Characteristics V IN = 5V, T A = 5ºC unless otherwise noted. Output Turn-On Delay Time (V INA /V = 5V; V /V = V; R LA = Ω; R LB = Ω) Output Turn-On Delay Time (V INA /V /V EN = 5V; R L = Ω) Output Voltage Channel A (top) (V) VOUT VOUT Output Voltage Channel B (bottom) (V) Output Voltage Channel A (top) (V) VOUT VOUT Output Voltage Channel B (bottom) (V) Time (5µs/div) Time (5µs/div) Output Turn-On Delay Time (V IN = 5V; R L = Ω) Output Turn-On Delay Time (V IN = V; R L = Ω) Voltage (top) (V) 5 EN V OUT I IN.5 Current (bottom) (A) Voltage (top) (V) EN I IN V OUT.. Current (bottom) (A) Time (5µs/div) Time (5µs/div) Output Turn-On (R L = Ω) Output Turn-On (V IN =.8V; R L = Ω) 7 EN.5 5.5 V EN Voltage (V) V OUT (FAST = V IN ) V OUT (FAST = GND) Voltage (V).5.5 -.5 V OUT (FAST = V IN ) V OUT (FAST = GND) Time (5µs/div) Time (µs/div) www.analogictech.com 8A.9.7..
Typical Characteristics V IN = 5V, T A = 5ºC unless otherwise noted. Output Turn-Off Delay Time (V IN = 5V; R L = Ω) Output Turn-Off Delay Time (V IN = V; R L = Ω). Voltage (top) (V) 5 EN I IN V OUT.8... Current (bottom) (A) Voltage (top) (V) EN I IN V OUT.. Current (bottom) (A) Time (5µs/div) Time (5µs/div) Output Turn-Off Delay Time (V IN =.8V; R L = Ω) Enable Voltage (top) (V) Output Voltage (bottom) (V).5.5.5.5 -.5 V EN V OUT Time (5µs/div) 8A.9.7.. www.analogictech.com 7
Functional Block Diagram INA OUTA Turn-On Slew Rate Control ON/OFF A Level Shift * FAST/ SLOW OUTB Turn-On Slew Rate Control ON/OFF B Level Shift * GND * - version only. Functional Description The is a family of flexible dual P-channel MOSFET power switches designed for high-side load switching applications. There are three versions of the with different turn-on and turn-off characteristics to choose from, depending upon the specific requirements of an application. The first version, the -, has a moderate turn-on slew rate feature, which reduces in-rush current when the MOSFET is turned on. This function allows the load switch to be implemented with either a small input capacitor or no input capacitor at all. During turn-on slewing, the current ramps linearly until it reaches the level required for the output load condition. The proprietary turn-on current control method works by careful control and monitoring of the MOSFET gate voltage. When the device is switched ON, the gate voltage is quickly increased to the threshold level of the MOSFET. Once at this level, the current begins to slew as the gate voltage is slowly increased until the MOSFET becomes fully enhanced. Once it has reached this point the gate is quickly increased to the full input voltage and the R DS(ON) is minimized. The second version, the -, is a very fast switch intended for high-speed switching applications. This version has no turn-on slew rate control and no special output discharge features. The final switch version, the -, has the addition of a minimized slew rate limited turn-on function and a shutdown output discharge circuit to rapidly turn off a load when the load switch is disabled through the ON/OFF pin. Using the FAST input pin on the -, the device can be manually switched to a slower slew rate. All versions of the operate with input voltages ranging from.5v to.5v. All versions of this device have extremely low operating current, making them ideal for battery-powered applications. The ON/OFF control pin is TTL compatible and will also function with.5v to 5V logic systems, making the an ideal level-shifting load switch. 8 www.analogictech.com 8A.9.7..
Applications Information Input Capacitor A μf or larger capacitor is typically recommended for C IN in most applications. A C IN capacitor is not required for basic operation; however, it is useful in preventing load transients from affecting upstream circuits. C IN should be located as close to the device VIN pin as practically possible. Ceramic, tantalum, or aluminum electrolytic capacitors may be selected for C IN. There is no specific capacitor equivalent series resistance (ESR) requirement for C IN. However, for higher current operation, ceramic capacitors are recommended for C IN due to their inherent capability over tantalum capacitors to withstand input current surges from low-impedance sources, such as batteries in portable devices. Output Capacitor For proper slew operation, a.μf capacitor or greater is required between VOUT and GND. Likewise, with the output capacitor, there is no specific capacitor ESR requirement. If desired, C OUT may be increased without limit to accommodate any load transient condition without adversely affecting the slew rate. Enable Function The features an enable / disable function. This pin (ON) is active high and is compatible with TTL or CMOS logic. To assure the load switch will turn on, the ON control level must be greater than.v. The load switch will go into shutdown mode when the voltage on the ON pin falls below.v. When the load switch is in shutdown mode, the OUT pin is tri-stated, and quiescent current drops to leakage levels below μa. Reverse Output-to-Input Voltage Conditions and Protection Under normal operating conditions, a parasitic diode exists between the output and input of the load switch. The input voltage should always remain greater than the output load voltage, maintaining a reverse bias on the internal parasitic diode. Conditions where V OUT might exceed V IN should be avoided since this would forward bias the internal parasitic diode and allow excessive current flow into the VOUT pin, possibly damaging the load switch. In applications where there is a possibility of V OUT exceeding V IN for brief periods of time during normal operation, the use of a larger value C IN capacitor is highly recommended. A larger value of C IN with respect to C OUT will effect a slower C IN decay rate during shutdown, thus preventing V OUT from exceeding V IN. In applications where there is a greater danger of V OUT exceeding V IN for extended periods of time, it is recommended to place a Schottky diode from V IN to V OUT (connecting the cathode to V IN and anode to V OUT ). The Schottky diode forward voltage should be less than.5v. Thermal Considerations and High Output Current Applications The is designed to deliver a continuous output load current. The limiting characteristic for maximum safe operating output load current is package power dissipation. In order to obtain high operating currents, careful device layout and circuit operating conditions must be taken into account. The following discussions will assume the load switch is mounted on a printed circuit board utilizing the minimum recommended footprint as stated in the Printed Circuit Board Layout Recommendations section of this datasheet. At any given ambient temperature (T A ), the maximum package power dissipation can be determined by the following equation: P D(MAX) T J(MAX) - T A = Constants for the are maximum junction temperature (T J(MAX) = 5 C) and package thermal resistance (θ JA = 7 C/W). Worst case conditions are calculated at the maximum operating temperature, T A = 85 C. Typical conditions are calculated under normal ambient conditions where T A = 5 C. At T A = 85 C, P D(MAX) = 57mW. At T A = 5 C, P D(MAX) = 9mW. The maximum continuous output current for the is a function of the package power dissipation and the R DS of the MOSFET at T J(MAX). The maximum R DS of the MOSFET at T J(MAX) is calculated by increasing the θ JA. The actual maximum junction temperature of is 5 C. However, good design practice is to derate the maximum die temperature to 5 C to prevent the possibility of over-temperature damage. 8A.9.7.. www.analogictech.com 9
maximum room temperature R DS by the R DS temperature coefficient. The temperature coefficient (TC) is 8ppm/ C. Therefore, at 5 C: R DS(MAX) = R DS(5 C) ( + TC ΔT)Ω R DS(MAX) = mω +.8 (5 C - 5 C)) R DS(MAX) =.mω For maximum current, refer to the following equation: I OUT(MAX) < P D(MAX) R DS For example, if V IN = 5V, R DS(MAX) =.mω, and T A = 5 C, I OUT(MAX) =.9A. If the output load current were to exceed.9a or if the ambient temperature were to increase, the internal die temperature would increase and the device would be damaged. Higher peak currents can be obtained with the. To accomplish this, the device thermal resistance must be reduced by increasing the heat sink area or by operating the load switch in a duty cycle manner. Duty cycles with peaks less than ms in duration can be considered using the method described in the High Peak Current Applications section of this datasheet. High Peak Output Current Applications Some applications require the load switch to operate at a continuous nominal current level with short duration, high-current peaks. Refer to the I DM specification in the Absolute Maximum Ratings table to ensure the s maximum pulsed current rating is not exceeded. The duty cycle for both output current levels must be taken into account. To do so, first calculate the power dissipation at the nominal continuous current level, and then add the additional power dissipation due to the short duration, high-current peak scaled by the duty factor. For example, a V system using an which has channel A operates at a continuous A load current level, and channel B operates at a continuous ma load current level and has short A current peaks, as in a GSM application. The current peak occurs for 57μs out of a.ms period. First, the current duty cycle is calculated: x % Peak Duty Cycle = = 57μs.ms % Peak Duty Cycle =.5% The load current is ma for 87.5% of the.ms period and A for.5% of the period. Since the Electrical Characteristics do not report R DS(MAX) for V operation, it must be approximated by consulting the chart of R DS(ON) vs. V IN. The R DS reported for 5V at ma and A can be scaled by the ratio seen in the chart to derive the R DS for V V IN at 5 C: mω mω/mω =.5mΩ. De-rated for temperature:.5mω ( +.8 (5 C - 5 C)) = 7.7mΩ. For channel A, the power dissipation for a continuous A load is calculated as follows: P D(CHA) = I OUT R DS = (A) 7.7mΩ = 7.7mW For channel B, the power dissipation for ma load is calculated as follows: P D(MAX) = I OUT R DS P D(mA) = (ma) 7.7mΩ P D(mA) =.75mW P D(87.5%D/C) = %DC P D(mA) P D(87.5%D/C) =.875.75mW P D(87.5%D/C) =.5mW The power dissipation for ma load at 87.5% duty cycle is.5mw. Now the power dissipation for the remaining.5% of the duty cycle at A is calculated: P D(MAX) = I OUT R DS P D(A) = (A) 7.7mΩ P D(A) = 57mW P D(.5%D/C) = %DC P D(A) P D(.5%D/C) =.5 57mW P D(.5%D/C) = 9.7mW Finally, the total power dissipation for channels A and B is determined as follows: P D(total) = P D(CHA) + P D(mA) + P D(A) P D(total) = 7.7mW +.5mW + 9.7mW P D(total) = 7mW The maximum power dissipation for the operating at an ambient temperature of 85 C is 7mW. The device in this example will have a total power dissipation of 57mW. This is well within the thermal limits for safe operation of the device; in fact, at 85 C, the will handle a A pulse for up to 5% duty cycle. At lower ambient temperatures, the duty cycle can be further increased. www.analogictech.com 8A.9.7..
Printed Circuit Board Layout Recommendations For proper thermal management, and to take advantage of the low R DS(ON) of the, a few circuit board layout rules should be followed: V IN and V OUT should be routed using wider than normal traces, and GND should be connected to a ground plane. For best performance, C IN and C OUT should be placed close to the package pins. Evaluation Board Layout The evaluation layout follows the printed circuit board layout recommendations and can be used for good applications layout. Refer to Figures through. Note: Board layout shown is not to scale. INA (.5V -.5V) C μf JP FAST/SLOW 7 U INA OUTA 8 FAST C.μF OUTA (.5V -.5V) C μf OUTB 5 GND IPS FTDFN-8 C.μF OUTB C, C μf X5R V (P/N: GRM88RA5KAD) C, C.μF X5R V (P/N: GRM88R7CKAD) Figure : IPS Evaluation Board Schematic. Figure : IPS Evaluation Board Top Side Layout. Figure : IPS Evaluation Board Bottom Side Layout. 8A.9.7.. www.analogictech.com
INA (.5V -.5V) C μf JP FAST/SLOW 8 U INA OUTA FAST C.μF OUTA (.5V-.5V) C μf 5 7 OUTB GND IFS FSC7JW-8 C.μF OUTB C, C μf X5R V (P/N: GRM88RA5KAD) C, C.μF X5R V (P/N: GRM88R7CKAD) Figure : IFS Evaluation Board Schematic. Figure 5: IFS Evaluation Board Top Side Layout. Figure : IFS Evaluation Board Bottom Side Layout. www.analogictech.com 8A.9.7..
Ordering Information Device Option Package Marking Part Number (Tape and Reel) - FTDFN-8 WKXYY IPS--T - FSC7JW-8 A8XYY IFS--T All AnalogicTech products are offered in Pb-free packaging. The term Pb-free means semiconductor products that are in compliance with current RoHS standards, including the requirement that lead not exceed.% by weight in homogeneous materials. For more information, please visit our website at http://www.analogictech.com/about/quality.aspx. Package Information FTDFN-8. ±.5 Index Area Detail "A". ±.5. ±.5 Top View Bottom View.5 ±.5.75 ±.5. +. -. Side View. ±.5 Pin Identification.5 ±.5.5 ±.5 Detail "A" All dimensions in millimeters.. XYY = assembly and date code.. Sample stock is generally held on part numbers listed in BOLD.. The leadless package family, which includes QFN, TQFN, DFN, FTDFN, TDFN and STDFN, has exposed copper (unplated) at the end of the lead terminals due to the manufacturing process. A solder fillet at the exposed copper edge cannot be guaranteed and is not required to ensure a proper bottom solder connection. 8A.9.7.. www.analogictech.com
FSC7JW-8.5 BSC.5 BSC.5 BSC.75 ±.. ±..5 ±.75. ±..85 ±.5. MAX.5 ±.5..5 ±. 7 ± ±.8REF.5 ±.5. ±. All dimensions in millimeters. Advanced Analogic Technologies, Inc. Scott Boulevard, Santa Clara, CA 955 Phone (8) 77- Fax (8) 77- Advanced Analogic Technologies, Inc. AnalogicTech cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in an AnalogicTech product. No circuit patent licenses, copyrights, mask work rights, or other intellectual property rights are implied. AnalogicTech reserves the right to make changes to their products or specifications or to discontinue any product or service without notice. Except as provided in AnalogicTech s terms and conditions of sale, AnalogicTech assumes no liability whatsoever, and AnalogicTech disclaims any express or implied warranty relating to the sale and/or use of AnalogicTech products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. In order to minimize risks associated with the customer s applications, adequate design and operating safeguards must be provided by the customer to minimize inherent or procedural hazards. Testing and other quality control techniques are utilized to the extent AnalogicTech deems necessary to support this warranty. Specific testing of all parameters of each device is not necessarily performed. AnalogicTech and the AnalogicTech logo are trademarks of Advanced Analogic Technologies Incorporated. All other brand and product names appearing in this document are registered trademarks or trademarks of their respective holders. www.analogictech.com 8A.9.7..