AIC1750 dual output low esr cap. low-dropout 150ma linear regulator analog integrations corporation si-soft research center ds-1750g-01 120908 3a1, no.1, li-hsin rd. i, science park, hsinchu 300, taiwan, r.o.c. tel: 886-3-5772500, fax: 886-3-5772510 www.analog.com.tw 1 features up to 150ma output current (each ldo). low quiescent current �j 50a at single output. low dropout �j 145mv at 100ma load current and 3.3v output voltage. high psrr �j60db at 1khz. independent shutdown controls. current limit and thermal protection. tiny sot-23-6, tsot-23-6 and dfn6l 2x2 package. applications cellular phones. pdas. digital still cameras. portable consumer equipments. description the AIC1750 is a dual output linear regulator in a tiny sot-23-6, tsot-23-6 and dfn6l 2x2 package. it is optimized for low esr ceramic capacitors operation and up to 150ma continuous current on each output. the AIC1750 offers high precision output voltage of 2%. at 100ma load current, a 145mv dropout is performed when output voltage is equal to 3.3v. the quality of low quiescent current and low dropout voltage makes this device ideal for battery power applications. the high ripple rejection and low noise of the AIC1750 provide enhanced performances for critical applications such as cellular phones, and pdas. the AIC1750 includes current limit and thermal shutdown protection. each of the output is controlled independently. typical application circuit vout1 6 en1 1 gnd 5 vin 2 vout2 4 en2 3 AIC1750 1 f c in 1 f c out1 1 f c out2 v in v out1 v out2
AIC1750 2 ordering information vout1 gnd vout2 vin en1 en2 pin configuration front view 1 3 4 6 2 5 sot-23-6 package type gt (sot-23-6) gl (sot-23-6) a ic1750-xxxxxxx packing type tr: tape & reel package type gt: sot-23-6 gl: sot-23-6 kt: tsot-23-6 kl: tsot-23-6 da: dfn6l 2x2 output2 voltage: vout2 a 1.1v b 1.2v : : v 3.2v w 3.3v x 2.85v example: AIC1750-ohpgttr vout1 = 2.5v, vout2 = 1.8v, with gt type pin configuration in sot-23-6 lead free package and tape & reel packing. AIC1750-capgltr vout1 = 1.3v, vout2 = 1.1v, with gl type pin configuration in sot-23-6 lead free package and tape & reel packing. * ldo output1 voltage and output2 voltage with every 0.1v a step. p: lead free commercial g: green package (dfn6l 2x2 only available in green package ) da (dfn6l 2x2) 5 1 4 2 6 3 en2 en1 vin vout2 gnd vout1 dfn6l 2x2 front view front view en2 en1 vout2 gnd vin vout1 6 4 1 2 3 5 sot-23-6 en2 en1 vout2 vin gnd vout1 6 4 1 2 3 5 tsot-23-6 front view front view en2 en1 vout2 gnd vin vout1 6 4 1 2 3 5 tsot-23-6 kt (tsot-23-6) kl (tsot-23-6) output1 voltage: vout1 a 1.1v b 1.2v : : v 3.2v w 3.3v x 2.85v
AIC1750 3 sot-23-6 marking part no. marking output voltage AIC1750-xxpgt bvxxp 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxpgl bwxxp 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxggt bvxxg 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxggl bwxxg 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) tsot-23-6 marking part no. marking output voltage AIC1750-xxpkt byxxp 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxpkl bzxxp 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxgkt byxxg 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) AIC1750-xxgkl bzxxg 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v)
AIC1750 4 dfn6l 2x2 marking part no. marking output voltage AIC1750-xxgda cyxxg 1st x -> vout1, 2nd x -> vout2 x=a,b,c?,w,x (a=1.1v, b=1.2v,c=1.3v,d=1.4v ???,w=3.3v, 0.1v a step, x=2.85v) absolute maximum ratings input vo ltage ....................................................................................................................................... 6v en pin voltage................................................................................................................. ................... 6v operating ambient temperature range t a ......................................................................... -40oc~85oc operating maximum junction temperature t j ............................................................................. 125o c storage temperature range t stg ..................................................................................... -65oc~150oc lead temperature (sol dering 10 se c.)......................................................................................... 26 0oc thermal resistance juncti on to case sot-23 -6 .............................................................115 c/w tsot-23-6 ...........................................................115 c/w dfn6l 2x2 ............................................................ 30 c/w thermal resistance juncti on to ambient sot-23 -6 .............................................................250 c/w tsot-23-6 ...........................................................250 c/w dfn6l 2x2 ..........................................................165 c/w (assume no ambient airflow, no heatsink) absolute maximum ratings are those values beyond which the life of a device may be impaired.
AIC1750 5 electrical characteristics (v in = v out + 1v, v en1 =v en2 = v in , t j =25 c, unless otherwise specified) (note 1) parameter test conditions symbol min. typ. max. unit input voltage (note 2) v in 2.0 5.5 v output voltage tolerance i out = 30ma v out -2 2 % continuous output current i out 150 ma quiescent current i out1 = 0ma & v en2 = 0v or i out2 = 0ma & v en1 = 0v i q 50 75 a gnd pin current i out1 = 150ma & v en2 = 0v or i out2 = 150ma & v en1 = 0v i gnd 55 75 a standby current v en1 =v en2 = 0 i stby 0.1 a output current limit v out = gnd i il 180 350 500 ma i out = 30 ma 550 750 i out = 100 ma 640 800 dropout voltage (1) i out = 150 ma v out =1.2v v drop1 800 1000 mv i out = 30 ma 85 150 i out = 100 ma 280 400 dropout voltage (2) i out = 150 ma v out =1.8v v drop2 410 600 mv i out = 30 ma 45 60 i out = 100 ma 145 200 dropout voltage (3) i out = 150 ma v out =3.3v v drop3 240 300 mv line regulation v in = v out + 1v to 5.5v ?v lir 10 mv load regulation i out = 1ma to 150ma ?v lor 15 60 mv ripple rejection f=1khz, ripple=0.5vp-p, psrr 60 db temperature coefficient tc 50 ppm/ �
thermal shutdown temperature v in = v out + 1v 150 �
thermal shutdown hysteresis 20 �
�� en pin specifications en pin current v en1 = v en2 = v in i en 0.1 1 a output on v enh 1.6 en input threshold output off v enl 0.25 v note 1: specifications are production tested at t a =25 c. specifications over the -40 c to 85 c operating temperature range are assu red by design, characterization and co rrelation with statistical quality controls (sqc). note 2: choose the maximum value of (v out +v drop ) or 2.0v as v in(min) .
AIC1750 6 typical performance characteristics -40-20 0 20406080 90 91 92 93 94 95 96 97 98 99 100 supply current ( a) ambient temperature ( o c) 2.5 3.0 3.5 4.0 4.5 5.0 5.5 0.90 0.92 0.94 0.96 0.98 1.00 1.02 1.04 1.06 1.08 1.10 1.12 1.14 1.16 1.18 1.20 output voltage (v) input voltage(v) iout 0ma 30ma 100ma v out =1.1v v in =5v, v out =1.1v fig. 1 supply current vs. temperature fig. 2 output voltage vs. input voltage -40-20 0 2040608 98.0 98.5 99.0 99.5 100.0 100.5 101.0 101.5 102.0 102.5 103.0 103.5 0 supply current ( a) ambient temperature ( o c) 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5. 5 v in =5v, v out =1.8v 1.30 1.35 1.40 1.45 1.50 1.55 1.60 1.65 1.70 1.75 1.80 1.85 output voltage (v) input voltage(v) iout 0ma 30ma 100ma v out =1.8v fig. 3 supply current vs. temperature fig. 4 output voltage vs. input voltage -40-200 2040608 89 90 91 92 93 94 95 96 97 98 99 100 0 ambient temperature ( o c) supply current ( a) 3 . 54 . 04 . 55 . 0 3.12 3.14 3.16 3.18 3.20 3.22 3.24 3.26 3.28 3.30 3.32 5 . 5 output voltage (v) input voltage(v) iout 0ma 30ma 100ma v =5v, v =3.3v in out v out =3.3v fig. 5 supply current vs. temperature fig. 6 output voltage vs. input voltage
AIC1750 7 30 40 50 60 70 80 90 100 110 120 130 140 150 400 450 500 550 600 650 700 750 800 850 25 o c 85 o c -40 o c dropout voltage (mv) output current (ma) -40-20 0 2040608 1.050 1.055 1.060 1.065 1.070 1.075 1.080 1.085 1.090 1.095 1.100 0 output voltage (v) ambient temperature ( o c) iout 0ma 30ma 100ma v in =5v, v out =1.1v v out =1.1v fig. 7 dropout voltage vs. output current fig. 8 output voltage vs. temperature 30 40 50 60 70 80 90 100 110 120 130 140 150 0 50 100 150 200 250 300 350 400 450 500 -40 o c 25 o c 85 o c dropout voltage (mv) output current (ma) -40-20 0 2040608 1.70 1.72 1.74 1.76 1.78 1.80 1.82 1.84 0 iout 0ma 30ma 100ma output voltage (v) ambient temperature ( o c) v out =1.8v v in =5v, v out =1.8v fig. 9 dropout voltage vs. output current fig. 10 output voltage vs. temperature 30 40 50 60 70 80 90 100 110 120 130 140 150 0 30 60 90 120 150 180 210 240 270 300 -40 o c 25 o c 85 o c dropout voltage (mv) output current (ma) -40-20 0 2040608 3.250 3.255 3.260 3.265 3.270 3.275 3.280 3.285 3.290 3.295 3.300 3.305 3.310 3.315 0 iout 0ma 30ma 100ma output voltage (v) ambient temperature ( o c) v in =5v, v out =3.3v v out =3.3v fig. 11 dropout voltage vs. output current fig. 12 output voltage vs. temperature
AIC1750 8 c in =c out1 =c out2 =1 f c in =c out1 =c out2 =1 f v in = 2.2v to 3.2v out p ut volta g e ri pp le input volta g e output voltage ripple output current i out = 1ma to 150ma fig. 13 load transient response at v in =5.5v, v out =1.1v fig. 14 line transient response at v out =1.1v, i out =150ma v in = 2.8v to 3.8v c in =c out1 =c out2 =1 f c in =c out1 =c out2 =1 f in p ut volta g e out p ut volta g e ri pp le output voltage ripple output current i out = 1ma to 150ma fig. 15 load transient response at v in =5.5v, v out =1.8v fig. 16 line transient response at v out =1.8v, i out =150ma c in =c out1 =c out2 =1 f v in = 4.3v to 5.3v c in =c out1 =c out2 =1 f in p ut volta g e output volta g e ripple output voltage ripple output current i out = 1ma to 150ma fig. 17 load transient response at v in =5.5v, v out =3.3v fig. 18 line transient response at v out =3.3v, i out =150ma
AIC1750 9 3.54.04.55.05.56 80 85 90 95 100 .0 vout=3.3v 100ma 30ma 0ma supply current ( a) input voltage(v) simulation verif y fig. 19 supply current vs. input voltage fig. 20 region of stable c out esr vs. load current i out1 = 1ma to 150ma c in =c out1 =c out2 =1 f i out1 = 1ma to 150ma c in =c out1 =c out2 =1 f output1 voltage ripple output1 voltage ripple output2 voltage ripple output2 voltage ripple out p ut1 cu r rent out p ut1 current fig. 21 cross talk at v in =3.8v, v out1 =1.8v, v out2 =2.8v, i out2 =150ma fig. 22 cross talk at v in =5.5v, v out1 =1.8v, v out2 =2.8v, i out2 =150ma
AIC1750 10 block diagram pin description vin pin - power inp ut. n/off controller. this pin isn?t allowed to float. out2 pin - output 2. gnd pin - ground. en1 pin - output 1 on/off controller. this pin isn?t allowed to float. en2 pin - output 2 o vout1 pin - output 1. v
AIC1750 11 application information the AIC1750 is a low-dropout, low quiescent-current, dual-output linear regulator for battery power applications. these parts are available with preset output voltages ranging from 1.1v to 3.3v, and the ly loads up to 150ma. e shut down to reduce the supply current to 0.1 a. this can protect the device from being damaged. rating of junction temperature must not be exceeded. ramic output capacitor for each regulator is d current? to choose proper ranges of voltage and temperature than other types. e low even when large is ssipation is: parts can supp shutdown the AIC1750 has two independent shutdown control inputs (en1 and en2). by connecting en1 pin to ground, output1 can be shut down. by connecting en2 pin to ground, output2 can be shut down. by connecting both of en1 pin and en2 pin to ground, the AIC1750 can b current limit the AIC1750 includes two independent current limiters, which monitor and control the maximum output current. if the output is overloaded or shorted to ground, thermal protection the AIC1750 includes two independent thermal- limiting circuits, which are designed to protect the device against overload condition. when the junction temperature exceeds t j =150oc, the thermal-limiting circuit turns off the pass transistor and allows the ic to cool. for continuous load condition, maximum input-output capacitors linear regulators require input and output capacitors to maintain stability. input capacitor at 1 f with a 1 f recommended. to avoid oscillation, it is recommended to follow the figure of ?region of stable c ce out esr vs. loa capacitor specifications. when choosing the input and output ceramic capacitors, x5r and x7r types are recommended because they retain their capacitance over wider power dissipation the maximum power dissipation of AIC1750 depends on the thermal resistance of its case and circuit board, the temperature difference between the die junction and ambient air, and the rate of airflow. the rate of temperature rise is greatly affected by the mounting pad configurati on on the pcb, the board material, and the ambient temperature. when the ic mounting with good thermal conductivity is used, the junction temperature will b power dissipation applies. the power dissipation across the device p = i out1 (v in -v out1 )+ i out2 (v in -v out2 ) the maximum power di ja max r where t a max-j )t-(t p = the ambient l conductivity to maintain low device temperature. j-max is the maximum allowable junction temperature (125 c), and t a is temperature suitable in application. as a general rule, the lower temperature is, the better reliability of the device is. so the pcb mounting pad should provide maximum therma
AIC1750 12 physical dimensions sot-23-6 c a a2 b with plating view b l1 l seating plane gauge plane 0.25 a1 section a-a base metal e1 d e aa e1 see view b e 0 0.90 0.30 1.50 2.60 2.80 0.08 0.30 0.05 e l1 l e1 c e e1 d b a2 a1 0.95 bsc 8 0.60 1.90 bsc 0.42 ref 1.30 1.70 3.00 3.00 0.22 0.50 0.15 0.95 min. s y m b o l a 1.45 max. sot-23-6 millimeters note : 1. refer to jedec mo-178ab. 2. dimension "d" does not include mold flash, protru sions or gate burrs. mold flash, protrusion or gate bu rrs shall not exceed 10 mil per side. 3. dimension "e1" does not include inter-lead flash or protrusions. 4. controlling dimension is millimeter, converted in ch dimensions are not necessarily exact.
AIC1750 13 tsot-23-6 c a a2 b with plating view b l1 l seating plane gauge plane 0.25 a1 section a-a base metal e1 d e aa e1 see view b e 0 0.70 0.30 1.50 2.60 2.80 0.08 0.30 0 e l1 l e1 c e e1 d b a2 a1 0.95 bsc 8 0.60 1.90 bsc 0.60 ref 0.90 1.70 3.00 3.00 0.22 0.50 0.10 - min. s y m b o l a 1.00 max. tsot-23-6 millimeters note : 1. refer to jedec mo-193aa. 2. dimension "d" does not include mold flash, protru sions or gate burrs. mold flash, protrusion or gate bu rrs shall not exceed 6 mil per side. 3. dimension "e1" does not include inter-lead flash or protrusions. 4. controlling dimension is millimeter, converted in ch dimensions are not necessarily exact.
AIC1750 14 dfn6l 2x2 e l d2 b a3 top view bottom view side view e 31 a seating plane 6 pin#1 d 4 e2 0.65 1.45 0.35 2.00 bsc 2.00 bsc millimeters min. s y m b o l a3 a0 . 7 0 max. 0.20 bsc 0.80 dfn 6l-2x2x0.75-0.65mm e e l e2 0.25 0.55 d2 d b 1.35 0.25 0.65 bsc 0.35 note : 1. dimension and tolerancing conform to asme y14.5m-1994 . 2.controlling dimensionsmillimeterconverted inch dimension are not necessarily exact. 3.dimension b applies to metallized terminal and is measured between 0.10 and 0.25 mm from terminal t ip.
AIC1750 15 note: information provided by aic is believed to be accurate and reliabl e. however, we cannot assume responsibility for use of any ci rcuitry other than circuitry entirely embodied in an aic product; nor for any infringement of patents or other rights of third parties that may result from its use. we reserve the right to change t he circuitry and specifications without notice. life support policy: aic does not authorize any aic product for use in life support devices and/or systems. life support device s or systems are devices or systems which, (i) are intended for surgic al implant into the body or (ii) support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user.
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