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| 1/12 march 2002 n dual input voltage (12v and 5v) n triple output voltage (2.6v, 3.3v, 8v) n 2.6v guaranteed i out up to 1.2a n 3.3v guaranteed i out up to 1.0a n 8v guaranteed i out up to 200ma n thermal and short circuit protection n guaranteed operating temperature range (0c to 125c) description this device contains three voltage regulators, all fixed output voltage, in one 7 pin surface mount package. the first is a 2.6 v regulator to power the integrated controller/p. the second is a 3.3v regulator to power the read channel chip, and memory chips requiring 3.3v the last is an 8v regulator to power the preamp chip. the bandgap reference, the 8v ground, and the substrate are all tied to a common ground pin, while the 2.6v and 3.3v ground is tied to a separate ground pin.this grounding scheme allows for improved noise isolation between the 8v regulator and the 2.6v and 3.3v regulators.the 2.6v and 3.3v regulators shall be respectively capable of 1.0a and 1.2a. the 8v regulator shall be capable of 200ma. it is housed in the spak (powerflex ? ) st3l01 triple voltage regulator v 2.6 schematic diagram spak-7l (powerflex ? ) obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s)
st3l01 2/12 absolute maximum ratings general operating condition thermal data connection diagram (top view) pin description ordering information (*) available in tape & reel with the suffix "r" symbol parameter value unit v cc supply voltage 18 v v dd isupply voltage 18 v v esd esd tolerance (human body model) 4kv t stg storage temperature range -65 to +150 c t j operating junction temperature range 0 to +150 c symbol parameter value unit v cc v cc supply voltage 4.75 to 5.25 v d v cc v cc ripple 0.15 v t r rise time (10% to 90%) referred to v cc 1v t f fall time (90% to 10%) referred to v cc 1v v dd v dd supply voltage 10.8 to 13.2 v d v dd v dd ripple 0.3 v t r rise time (10% to 90%) referred to v dd 1v t f fall time (90% to 10%) referred to v dd 1v t al operating ambient temperature range 0 to 70 m s symbol parameter spak-7l unit r thj-case thermal resistance junction-case 2 c/w spak-7l pin n symbol name and function 1 gnd 1,2 v o1 and v o2 regulators gnd pin 2v o2 second output pin: bypass with a 0.1 m f capacitor to gnd 3v cc input pin: bypass with a 0.1 m f capacitor to gnd 4gnd 3 v o3 regulators gnd pin 5v o3 third output pin: bypass with a 0.1 m f capacitor to gnd 6v dd input pin: bypass with a 0.1 m f capacitor to gnd 7v o1 first output pin: bypass with a 0.1 m f capacitor to gnd type spak (power flex ? ) 7 leads (*) st3l01 st3l01k7 obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 3/12 typical application circuit note: to improve noise figure of the 8v vreg connect this capacitor to the gnd 8v pin. c cc , c dd , c o1 , c o2 and c o3 capacitors must be located not more than 0.5" from the output pins of the device. form more details about capacitors read the "application hints" electrical characteristics (v cc =5v, v dd =12v, c cc =1 m f (tantalum), c dd =0.1 m f (x7r), c o1 =c o2 =c o3 =0.11 m f (x7r) t j =0 to 125c unless otherwise specified. typical values are referred at t j =25c, i fl1 =1.2a, i fl2 =1.0a, i fl3 =0.2a, symbol parameter test conditions min. typ. max. unit v o1 output voltage 1 i o1 = 10ma t j = 25c 2.575 2.6 2.626 v i o1 = 0 to i fl1 v cc = 4.75 to 5.25v t j = 0 to 125c 2.55 2.6 2.65 v dd = 0 to 10.8v i o1 = 0.5a 2.2 2.65 v o2 output voltage 2 i o2 = 10ma t j = 25c 3.23 3.3 3.37 v i o2 = 0 to i fl2 v cc = 4.75 to 5.25v t j = 0 to 125c 3.2 3.3 3.4 v dd = 0 to 10.8v i o2 = 0.5a 2.92 3.4 v o3 output voltage 3 i o3 = 10ma t j = 25c 7.84 8 8.16 v i o3 = 0 to i fl3 v dd = 10.8 to 13.2v t j = 0 to 125c 7.76 8 8.24 d v o line regulation 1 i o = 10ma v cc = 5% v dd = 10% <0.2 %v o d v o load regulation 1 i o = 0.01 to i fl (note 1) <0.4 %v o v d1 dropout voltage 1 i o1 = i fl1 (note 2) 1.3 1.9 v v d2 dropout voltage 2 i o2 = i fl2 (note 2) 1.13 1.4 v v d3 dropout voltage 3 i o3 = i fl3 (note 2) 1.6 2.2 v t tr transient response (note 3, 7) <1 m s i ol1 output 1 current limit d v o = 125mv 1.5 2.1 2.5 a i ol2 output 2 current limit d v o = 165mv 1.1 1.7 2.5 a i ol3 output 3 current limit d v out = 400mv 0.25 0.4 0.5 a i o1 output 1 minimum load current (note 4, 7) 0 ma i o2 output 2 minimum load current (note 4, 7) 0 ma i o3 output 3 minimum load current (note 4, 7) 0 ma obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 4/12 note 1: low duty cycle pulse testing with kelvin connections are required in order to maintain accurate data note 2: dropout voltage is defined as the minimum differential voltage between v i and v o required to mantain regulation at v o . it is measured when the output voltage drops 100mv below its nominal value. note 3: transient response is defined with a step change in load from 10ma to i fl /2 as the time from the load step until the output voltage reaches its minimum value. note 4: minimum load current is defined as the minimum current required at the output in order to maintain regulation for the o utput voltage. note 5: the regulator shall withstand 100000 reverse bias discharges of the maximum output capacitance, with no degradation, wh en the input voltage is switched to ground in 1 m s. note 6: temperature stability is the change in output from nominal over the operating temperature range. note 7: guaranteed by design, not tested in production. application hints external capacitors the st3l01 requires external capacitors for stability. we suggest to solder both capacitors as close as possible to the relative pins. input capacitors an input capacitor, whose value is at least 0.1 m f, is required on the v dd input; the amount of the input capacitance can be increased without limit. any good quality tantalum or ceramic low esr capacitor may be used at the v dd input. any input capacitor, whose value is at least 1 m f is instead required on the v cc input; the amount of this input capacitance can be increased without limit. tantalum or aluminum electrolitic capacitor can be used at the v cc input; ceramic, low esr capacitor are not recommended. both capacitors must be located at a distance of not modre than 0.5" from the input pins of the device and returned to a clean analog ground. output capacitor the st3l01 is designed specifically to work with ceramic and tantalum capacitors. the test results of the st3l01 stability using multilayer ceramic capacitors show that a minimum value of 0.1 m f is needed for the three regulators. this value can be increased for even better transient response and noise performance. surface-mountable solid tantalum capacitors offer a good combination of small physical size for the capacitance value and esr in the range need by the st3l01. the test results show good stability for both outputs with values of at least 0.1 m f. also this capacitor value can be increased without limit for even better performance such a transient response and noise. important ; the output capacitor must maintain its esr in the stable region over the full operating temperature to assure stability. also , capacitor tolerance and variation with temperature must be considered to assure that the minimum amount of capacitance is provided at all times. for this reason, when a caramic multilayer capacitor is used, the better choise for temperature coefficent is the x7r type, which holds the capacitance within 15% . the output capacitor should be located not more than 0.5" from the output pins of the device and returned to a clean analog ground. c o output capacitor (note 5, 7) 0.1 m f c cc input capacitor (note 5) 1.0 m f c dd input capacitor (note 5) 0.1 m f reg therm therma regulation i out = i fl , t pulse = 30ms (note 7) 0.1 0.3 %/w svr1 supply voltage rejection (v cc to output 1) b = 100hz to 100khz i o1 = i fl1 /10 v cc = 4.75 to 5.25v (note 7) 30 >40 db svr2 supply voltage rejection (v cc to output 2) b = 100hz to 100khz i o2 = i fl2 /10 v cc = 4.75 to 5.25v (note 7) 30 >40 db svr3 supply voltage rejection (v dd to output 3) b = 100hz to 100khz i o3 = i fl3 /10 v dd = 10.8 to 13.2v (note 7) 40 >50 db i vcc v cc quiescent current i o1 = i o2 = i o3 = 0 7 10 ma i vdd v dd quiescent current i o1 = i o2 = i o3 = 0 13 20 ma en output noise b = 10hz to 10khz (note 7) 0.003 %v out d v o temperature stability i o = 10ma (note 6, 7) 0.5 %v out d v o long term stability t j = 125c, 1000hrs (note 7) 0.3 %v out symbol parameter test conditions min. typ. max. unit obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 5/12 typical characteristics (c cc =1 m f (tant), c dd =100nf (x7r), all c o =100nf (x7r)) figure 1 : output voltage vs temperature figure 2 : output voltage vs temperature figure 3 : output voltage vs temperature figure 4 : load regulation vs temperature figure 5 : load regulation vs temperature figure 6 : load regulation vs temperature obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 6/12 figure 7 : dropout voltage vs temperature figure 8 : dropout voltage vs temperature figure 9 : dropout voltage vs temperature figure 10 : dropout voltage vs output current figure 11 : dropout voltage vs output current figure 12 : dropout voltage vs output current obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 7/12 figure 13 : current limit vs temperature figure 14 : current limit vs temperature figure 15 : current limit vs temperature figure 16 : output voltage vs output current figure 17 : output voltage vs output current figure 18 : output voltage vs output current obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 8/12 figure 19 : quiescent current vs temperature figure 20 : quiescent current vs temperature figure 21 : supply voltage rejection vs frequency figure 22 : supply voltage rejection vs frequency figure 23 : supply voltage rejection vs frequency figure 24 : supply voltage rejection vs output current obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 9/12 figure 25 : supply voltage rejection vs output current figure 26 : supply voltage rejection vs output current figure 27 : supply voltage rejection vs temperature figure 28 : line transient figure 29 : line transient figure 30 : line transient v cc = 4 .75 to 5. 2 5 v , v dd = 12v , i o1 = i o2 = 10 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) v cc = 4 . 75 t o 5 . 25v , v dd = 12v , i o1 = i o2 = 10 m a , c cc = 1 m f (t an t) , c dd =100nf (x7r), all c o =100nf (x7r) v cc = 4 .75 to 5. 2 5 v , v dd = 12v , i o1 = i o2 = 10 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 10/12 figure 31 : line transient figure 32 : line transient figure 33 : line transient figure 34 : load transient figure 35 : load transient figure 36 : load transient v cc =5 v , v dd = 10 .7 to 13 . 2v , i o3 = 10 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) v cc = 5v , v dd = 10 . 7 t o 13 . 2v , i o3 = 10 m a , c cc = 1 m f (t an t) , c dd =100nf (x7r), all c o =100nf (x7r) v cc =5 v , v dd = 10 .7 to 13 . 2v , i o3 = 10 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) v cc =5 v , v dd = 12v , i o1 = 10 to 600 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) v cc = 5v , v dd = 12v , i o1 = 10 t o 600 m a , c cc = 1 m f (t an t) , c dd =100nf (x7r), all c o =100nf (x7r) v cc =5 v , v dd = 12v , i o1 = 10 to 600 m a , c cc = 1 m f ( tant ) , c dd =100nf (x7r), all c o =100nf (x7r) obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 11/12 dim. mm. inch min. typ max. min. typ. max. a 1.78 2.03 0.070 0.080 a2 0.03 0.13 0.001 0.005 c 0.25 0.010 c1 0.25 0.010 d 1.02 1.27 0.040 0.050 d1 7.87 8.13 0.310 0.320 f 0.63 0.79 0.025 0.031 g 1.27 0.050 g1 7.62 0.3 h1 5.59 0.220 h2 9.27 9.52 0.365 0.375 h3 8.89 9.14 0.350 0.360 l 10.41 10.67 0.410 0.420 l1 7.49 0.295 l2 8.89 9.14 0.350 0.360 m 0.79 1.04 0.031 0.041 n 0.25 0.010 v3? 6?3? 6? spak-7l mechanical data po13f2/a obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) st3l01 12/12 information furnished is believed to be accurate and reliable. however, stmicroelectronics assumes no res ponsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result f rom its use. no license is granted by implication or otherwise under any patent or patent rights of stmicroelectronics. specificati ons mentioned in this publication are subject to change without notice. this publication supersedes and replaces all information previously supplied. stmicroelectronics products are not authorized for use as critical components in life support devi ces or systems without express written approval of stmicroelectronics. ? the st logo is a registered trademark of stmicroelectronics ? 2002 stmicroelectronics - printed in italy - all rights reserved stmicroelectronics group of companies australia - brazil - canada - china - finland - france - germany - hong kong - india - israel - italy - japan - malaysia - malt a - morocco singapore - spain - sweden - switzerland - united kingdom - united states. ? http://www.st.com obsolete product(s) - obsolete product(s) obsolete product(s) - obsolete product(s) |
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