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www.ams.com/dc-dc_step-down revision 1.10 1 - 16 as1346-49 dual step-down converter with battery monitoring 1 general description the as1346, as1347, as1348, AS1349 family is a high-efficiency, constant-frequency dual buck converter available with fixed voltage versions. the device provides two independent dc/dc converters with output currents between 0.5a and 1.2a. the wide input voltage range (2.7v to 5.5v), automatic powersave mode and minimal external component requirements make the as134x family perfect for ssd and many other battery-powered applications. in shutdown mode the typical supply current decreases to 1 a. the highly efficient duty cycle (100%) provides low dropout operation, prolonging battery life in portable systems. an internal synchronous switching scheme increases efficiency and eliminates the need for an external schottky diode. the fixed switching frequency (2.0mhz) allows the use of small surface mount inductors. the integrated monitoring function can be configured that either the output voltage (power okay function ) or the input voltage (battery monitoring function) can be supervised. the as1346-49 is available in a 12-pin tdfn 3x3mm package. 2 key features ?? high efficiency: up to 95% ?? output current: see table 1 ?? input voltage range: 2.7v to 5.5v ?? output voltage range: 1.2v to 3.6v (available in 100mv steps) ?? constant frequency operation: 2.0mhz ?? 180o out of phase operation ?? low battery detection ?? low dropout operation: 100% duty cycle ?? shutdown mode supply current: ? 1 a ?? no schottky diode required ?? output disconnect in shutdown ?? non standard variants available within two weeks ?? 12-pin tdfn 3x3mm package 3 applications the device is ideal for ssd applications, mobile communication devices, laptops and pdas, ultra-low-power systems, threshold detectors/discriminators, telemetry and remote systems, medical instruments, or any other space-limited application with low power- consumption requirements. table 1. available products devices i out1 i out2 as1346 1.2a 0.5a as1347 0.5a 0.5a as1348 0.5a 0.95a AS1349 1.2a 1.2a as1346 c out1 c in v in 2.7v to 5.5v v out1 3.3v 1200ma figure 1. as1346 - typical application diagram with pok function sw1 c out2 v out2 1.8v 500ma fb1 fb2 sw2 agnd en2 pvin vdd en1 lbo lbi l1 = 3.3 h pok function l2 = 3.3 h pvin pgnd
www.ams.com/dc-dc_step-down revision 1.10 2 - 16 as1346-49 datasheet - pin assignments 4 pin assignments figure 2. pin assignments (top view) 4.1 pin descriptions table 2. pin descriptions pin number pin name description 1 sw1 switch node1 connection to inductor. this pin connects to the drains of the internal main and synchronous power mosfet switches. 2, 11 pvin power supply connector. this pin must be closely decoupled to pgnd with a ? 4.7 f ceramic capacitor. 3 en1 enable1 input. driving this pin above 1.2v enables v out1 . driving this pin below 0.5v puts the device in shutdown mode. in shutdown mode all functions are disabled, drawing ? 1 a supply current. this pin should not be left floating. 4 fb1 feedback pin 1. feedback input to the error amplifier, connect this pin to v out1 . the output can be factory set from 1.2v to 3.6v. for further information see ordering information on page 15 . 5 en2 enable2 input. driving this pin above 1.2v enables v out2 . driving this pin below 0.5v puts the device in shutdown mode. in shutdown mode all functions are disabled, drawing ? 1 a supply current. this pin should not be left floating. 6 lbo low battery comperator output. this open-drain output is low when: - the voltage on lbi is higher than 1.2v or - lbi is connected to gnd and v out1 is below 92.5% of its nominal value. 7 lbi low battery comperator input. 1.2v threshold. may not be left floating. if connected to gnd, lbo is working as output power okay for v out1 . 8 agnd analog ground. 9 fb2 feedback 2 pin. feedback input to the error amplifier, connect this pin to v out2 . the output can be factory set from 1.2v to 3.6v. for further information see ordering information on page 15 . 10 vdd supply connector. connect this pin to pvin 12 sw2 switch node2 connection to inductor. this pin connects to the drains of the internal main and synchronous power mosfet switches. 13 pgnd exposed pad. the exposed pad must be connected to agnd. ensure a good electrical connection to the pcb to achieve optimal thermal performance. as1346 pv in 2 fb1 4 sw1 1 en1 3 fb2 9 v dd 10 pv in 11 sw2 12 13 en2 5 agnd 8 lbo 6 lbi 7
www.ams.com/dc-dc_step-down revision 1.10 3 - 16 as1346-49 datasheet - absolute maximum ratings 5 absolute maximum ratings stresses beyond those listed in table 3 may cause permanent damage to the device. these are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in electrical characteristics on page 4 is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. table 3. absolute maximum ratings parameter min max units notes electrical parameters vdd, pvin to agnd -0.3 +7.0 v pgnd to agnd -0.3 +0.3 v en, fb agnd - 0.3 vdd + 0.3 v 7.0v max sw pgnd - 0.3 pvin + 0.3 v pvin to vdd -0.3 +0.3 v electrostatic discharge human body model 1 kv norm: mil 883 e method 3015 temperature ranges and storage conditions junction temperature (t j-max ) +150 oc storage temperature range -55 +150 oc package body temperature +260 oc the reflow peak soldering temperature (body temperature) specified is in accordance with ipc/ jedec j-std-020 ?moisture/reflow sensitivity classification for non-hermetic solid state surface mount devices?. the lead finish for pb-free leaded packages is matte tin (100% sn). humidity non-condensing 5 85 % moisture sensitive level 1 represents a max. floor life time of unlimited
www.ams.com/dc-dc_step-down revision 1.10 4 - 16 as1346-49 datasheet - electrical characteristics 6 electrical characteristics pvin = vdd = en = 5v, unless otherwise noted . typical values are at t a =25c. all limits are guaranteed. the parameters with min and max values are guaranteed with production tests or sqc (statistical quality control) methods. table 4. electrical characteristics symbol parameter conditions min typ max units t a operating temperature range -40 +85 c t j operating junction temperature range -40 +125 c v in input voltage range v in ?? v out 2.7 5.5 v v out output voltage range (see table 8 on page 15) 1.2 3.6 v i q quiescent supply current 1 2 2.8 ma i out1 output current 1 as1346, v out1 = 3.3v 1200 ma as1347 500 ma as1348 500 ma AS1349 1200 ma i out2 output current 2 as1346, v out2 = 1.8v 500 ma as1347 500 ma as1348 950 ma AS1349 1200 ma i shdn shutdown current 0.1 1 a regulation v out1 output voltage 1 as1346, i out1 = 100ma 3.234 3.3 3.366 v accuracy +2 % v out2 output voltage 2 as1346, i out2 = 100ma 1.764 1.8 1.836 v accuracy +2 % line transient response v in = 4.5v to 5.5v, i out1 = 500ma, v out1 = 3.3v, en2 = 0v 50 mvpk load transient response v in = 5v, i out1 = 0 to 500ma, v out1 = 3.3v, en2 = 0v 50 mvpk f osc oscillator frequency 1.8 2 2.2 mhz t on turn on time 350 s dc-dc switches i sw1 sw1 current limit as1346 1.55 a i sw2 sw2 current limit as1346 800 ma r dson1(p) pin-pin resistance for pmos1 v dd = 5.0v, i sw = 200ma 150 m ? r dson1(n) pin-pin resistance for nmos1 v dd = 5.0v, i sw = 200ma 250 m ?
www.ams.com/dc-dc_step-down revision 1.10 5 - 16 as1346-49 datasheet - electrical characteristics r dson2(p) pin-pin resistance for pmos2 v dd = 5.0v, i sw = 200ma 150 m ? r dson2(n) pin-pin resistance for nmos2 v dd = 5.0v, i sw = 200ma 250 m ? enable v ih,en logic high input threshold 1.2 v v ih,en logic low input threshold 0.5v v low battery & power-ok v lbi lbi threshold falling edge 1.16 1.2 1.24 v lbi hysteresis 10 mv lbi leakage current lbi = 5v, t a = 25c 1 na lbo voltage low 2 i lbo = 0.1ma 0.05 v lbo leakage current lbo = 5v, t a = 25c 1 na power-ok threshold lbi = 0v, falling edge 85 88 90 % 1. the dynamic supply current is higher due to the gate charge delivered at the switching frequency. the quiescent current is me asured while the dc-dc converter is not switching. 2. lbo goes low in startup mode as well as during normal operation if, 1) the voltage at the lbi pin is higher than lbi threshold. 2) the voltage at the lbi pin is below 0.1v (connected to gnd) and v out1 is below 92.5% of its nominal value. table 4. electrical characteristics symbol parameter conditions min typ max units
www.ams.com/dc-dc_step-down revision 1.10 6 - 16 as1346-49 datasheet - t ypical operating characteristics 7 typical operating characteristics figure 3. as1346 efficiency vs. i out , v out 1 = 3.3v figure 4. as1346 efficiency vs. i out , v out 2 = 1.8v figure 5. as1346 efficiency vs. v in , v out 1 = 3.3v figure 6. as1346 efficiency vs. v in , v out 2 = 1.8v figure 7. efficiency vs. i out , v out 1 = 2.5v figure 8. efficiency vs. i out , v out 2 = 1.2v
www.ams.com/dc-dc_step-down revision 1.10 7 - 16 as1346-49 datasheet - t ypical operating characteristics figure 9. as1346 load regulation; v in = 4.0v, v out 1 = 3.3v figure 10. as1346 load regulation; v in = 4.0v, v out 2 =1.8v figure 11. as1346 line regulation, v out 1 = 3.3v figure 12. as1346 line regulation, v out 2 = 1.8v ldo mode figure 13. as1346 v out vs. temp.; v in = 5.5v, i out = 1a figure 14. as1346 v out vs. temp.; v in = 5.5v, i out = 500ma
www.ams.com/dc-dc_step-down revision 1.10 8 - 16 as1346-49 datasheet - t ypical operating characteristics figure 15. as1346 i q vs. v in figure 16. as1346 i q vs. v in , both v out enabled
www.ams.com/dc-dc_step-down revision 1.10 9 - 16 as1346-49 datasheet - detailed description 8 detailed description the as1346, as1347, as1348, AS1349 family is a high-efficiency buck converter that uses a constant-frequency current-mode archi tecture. the device contains two internal mosfet switches and is available with a fixed output voltage (see ordering information on page 15) . figure 17. as1346 - block diagram mosfet control logic shutdown control main control soft start current sense pvin pwm comp vdd error amplifier fb1 en1 sw1 agnd as1346 mosfet control logic soft start oscillator current sense pwm comp error amplifier fb2 en2 pvin vdd sw2 lbo lbi power-ok compare logic pgnd
www.ams.com/dc-dc_step-down revision 1.10 10 - 16 as1346-49 datasheet - detailed description 8.1 main control loop during normal operation, the internal top power mosfet is turned on each cycle when the oscillator sets the rs latch. this swit ch is turned off when the current comparator resets the rs latch. the peak inductor current (i pk ) at which icomp resets the rs latch, is controlled by the error amplifier. when i load increases, v fb decreases slightly relative to the internal 0.6v reference, causing the error amplifier?s output voltage to increase until the average inductor current matches the new load current. when the top mosfet is off, the bottom mosfet is turned on until the inductor current starts to reverse as indicated by the cur rent reversal comparator, or the next clock cycle begins. the over-voltage detection comparator guards against transient overshoots >7.8% by turning the main switch off and keeping it off until the transient is removed. 8.2 short-circuit protection the short-circuit protection turns off the power switches as long as the short is applied. when the short is removed the device is continuing normal operation. 8.3 dropout operation the as1346, as1347, as1348, AS1349 is working with a low input-to-output voltage difference by operating at 100% duty cycle. in this state, the pmos is always on. this is particularly useful in battery-powered applications with a 3.3v output. the as1346, as1347, as1348, AS1349 allows the output to follow the input battery voltage as it drops below the regulation volta ge. the quiescent current in this state is reduced to a minimal value, which aids in extending battery life. this dropout (100% duty-cy cle) operation achieves long battery life by taking full advantage of the entire battery range. the input voltage requires maintaining regulation and is a function of the output voltage and the load. the difference between the minimum input voltage and the output voltage is called the dropout voltage. the dropout voltage is therefore a function of the on-resistance of the internal pmos (r ds(on)pmos ) and the inductor resistance (dcr) and this is proportional to the load current. note: at low v in values, the r ds(on) of the p-channel switch increases (see electrical characteristics on page 4) . therefore, power dissipa- tion should be taken in consideration. 8.4 shutdown connecting en to gnd or logic low places the as1346, as1347, as1348, AS1349 in shutdown mode and reduces the supply current to 0.1 a. in shutdown the control circuitry and the internal nmos and pmos turn off and sw becomes high impedance disconnecting the input from the output. the output capacitance and load current determine the voltage decay rate. for normal operation connect en to v in or logic high. note: pin en should not be left floating. 8.4.1 power-ok and low-battery-detect functionality lbo goes low in startup mode as well as during normal operation if, - the voltage at the lbi pin is above lbi threshold (1.2v). this can be used to monitor the battery voltage. - lbi pin is connected to gnd and v out1 is below 92.5% of its nominal value. lbo works as a power-ok signal in this case. the lbi pin can be connected to a resistive-divider to monitor a particular definable voltage and compare it with a 1.2v intern al reference. if lbi is connected to gnd (see figure 1 on page 1) an internal resistive-divider is activated and connected to the output. therefore, the power-ok functionality can be realized with no additional external components. the power-ok feature is not active during shutdown. to obtain a logic-level output, connect a pull-up resistor from pin lbo to pin v out or v dd . larger values for this resistor will help to minimize current consumption; a 100k ? resistor is perfect for most applications (see figure 18 on page 11) . for the circuit shown in the left of figure 18 on page 11 , the input bias current into lbi is very low, permitting large-value resistor-divider networks while maintaining accuracy. place the resistor-divider network as close to the device as possible. use a defined resistor for r 2 and then calculate r 1 as: where: v lbi (the internal sense reference voltage) is 1.2v. in case of the lbi pin is connected to gnd, an internal resistor-divider network is activated and compares the output voltage w ith a 92.5% voltage threshold (see as1346 - typical application diagram with pok function on page 1) . for this particular power-ok application, no external resistive components (r1 and r2) are necessary. (eq 1) r 1 r 2 v in v lbi ------------ 1 ? ?? ?? ? =
www.ams.com/dc-dc_step-down revision 1.10 11 - 16 as1346-49 datasheet - detailed description figure 18. typical application diagram with adjustable battery monitoring 8.5 thermal shutdown due to its high-efficiency design, the as1346 will not dissipate much heat in most applications. however, in applications where the as1346 is running at high ambient temperature, uses a low supply voltage, and runs with high duty cycles (such as in dropout) the heat di ssipated may exceed the maximum junction temperature of the device. as soon as the junction temperature reaches approximately 150oc the as1346 goes in thermal shutdown. in this mode the internal pmos & nmos switch are turned off. the device will power up again, as soon as the temperature falls below +140oc again. r3 r1 r2 as1346 c out1 c in v in 4.5v to 5.5v v out1 3.3v 1200ma sw1 c out2 v out2 1.8v 500ma fb1 fb2 sw2 agnd en2 pvin vdd en1 lbi lbo l1 = 3.3 h l2 = 3.3 h pvin pgnd
www.ams.com/dc-dc_step-down revision 1.10 12 - 16 as1346-49 datasheet - application information 9 application information 9.1 component selection only three power components are required to complete the design of the buck converter. for the adjustable lbi two external resi stors are needed. 9.2 inductor selection for the external inductor, a 3.3 h inductor is recommended. minimum inductor size is dependant on the desired efficiency and output current. inductors with low core losses and small dcr at 2mhz are recommended. calculation of i max : 9.3 capacitor selection a 10 f capacitor is recommended for c in as well as a 10 f for c out . small-sized x5r or x7r ceramic capacitors are recommended as they retain capacitance over wide ranges of voltages and temperatures. 9.3.1 input and output capacitor selection low esr input capacitors reduce input switching noise and reduce the peak current drawn from the battery. also low esr capacito rs should be used to minimize v out ripple. multi-layer ceramic capacitors are recommended since they have extremely low esr and are available in small footprints. for input decoupling the ceramic capacitor should be located as close to the device as practical. a 22 f input capacitor is sufficient for most applications. larger values may be used without limitations. a 2.2 f to 10 f output ceramic capacitor is sufficient for most applications. larger values up to 22 f may be used to obtain extremely low output voltage ripple and improve transient response. table 5. recommended inductor l dcr current rating 3.3 h ?? m ? i max table 6. recommended input and output capacitor c tc code rated voltage c in 10 - 47 f x5r 6.3v c out1 , c out2 2.2 - 10 f x7r 25v (eq 2) i max i out 1 v out 1 ? i out 2 v out 2 ? + 07 ? v in ? -------------------------------------------------------------------------------------- =
www.ams.com/dc-dc_step-down revision 1.10 13 - 16 as1346-49 datasheet - package drawings and markings 10 package drawings and markings figure 19. 12-pin tdfn 3x3mm marking table 7. packaging code yywwqzz xxxx yy ww q zz marketing code year manufacturing week plant identifier free choice / traceability code
www.ams.com/dc-dc_step-down revision 1.10 14 - 16 as1346-49 datasheet - package drawings and markings figure 20. 12-pin tdfn 3x3mm package
www.ams.com/dc-dc_step-down revision 1.10 15 - 16 as1346-49 datasheet - ordering information 11 ordering information the device is available as the standard products listed below. receive samples within 2 weeks for any non standard output voltage variant! note: all products are rohs compliant. buy our products or get free samples online at icdirect: http://www.ams.com/icdirect technical support is found at http://www.ams.com/technical-support for further information and requests, please contact us mailto:sales@ams.com or find your local distributor at http://www.ams.com/distributor table 8. ordering information ordering code marking channel vout iout description delivery form package as1346-btdt-3318 assl out1 3.3v 1.2a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 1.8v 0.5a as1347-btdt-1812 asu6 out1 1.8v 0.5a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 1.2v 0.5a as1347-btdt-3310 asu7 out1 3.3v 0.5a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 1.0v 0.5a as1348-btdt-3312 astz out1 3.3v 0.5a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 1.2v 0.95a as1346-btdt-xxyy 1 1. non-standard devices from 1.2v to 3.6v are available in 100mv steps. for more information and inquiries contact http://www.ams.com/contact tbd out1 xx 1.2a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 yy 0.5a as1347-btdtxxyy 1 tbd out1 xx 0.5a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 yy 0.5a as1348-btdtxxyy 1 tbd out1 xx 0.5a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 yy 0.95a AS1349-btdtxxyy 1 tbd out1 xx 1.2a dual step-down converter with battery monitoring tape and reel 12-pin tdfn 3x3mm out2 yy 1.2a
www.ams.com/dc-dc_step-down revision 1.10 16 - 16 as1346-49 datasheet copyrights copyright ? 1997-2011, ams ag, tobelbaderstrasse 30, 8141 unterpremstaetten, austria-europe. trademarks registered ?. all right s reserved. the material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written con sent of the copyright owner. all products and companies mentioned are trademarks or registered trademarks of their respective companies. disclaimer devices sold by ams ag are covered by the warranty and patent indemnification provisions appearing in its term of sale. ams ag makes no warranty, express, statutory, implied, or by description regarding the information set forth herein or regarding the freedom of the described devices from patent infringement. ams ag reserves the right to change specifications and prices at any time and without notice. therefore, prior to designing this product into a system, it is necessary to check with ams ag for current information. this product is intended for use in normal commercial applications. applications requiring extended temperature range, unusual environmental requirements, or high reliabi lity applications, such as military, medical life-support or life-sustaining equipment are specifically not recommended without addi tional processing by ams ag for each application. for shipments of less than 100 parts the manufacturing flow might show deviations from the stan dard production flow, such as test flow or test location. the information furnished here by ams ag is believed to be correct and accurate. however, ams ag shall not be liable to recipie nt or any third party for any damages, including but not limited to personal injury, property damage, loss of profits, loss of use, interruptio n of business or indirect, special, incidental or consequential damages, of any kind, in connection with or arising out of the furnishing, perfo rmance or use of the technical data herein. no obligation or liability to recipient or any third party shall arise or flow out of ams ag rendering o f technical or other services. contact information headquarters ams ag tobelbaderstrasse 30 a-8141 unterpremstaetten, austria tel: +43 (0) 3136 500 0 fax: +43 (0) 3136 525 01 for sales offices, distributors and representatives, please visit: http://www.ams.com/contact

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