1 LT1620/lt1621 rail-to-rail current sense amplifier s f ea t u re n accurate output current programming n usable in charging applications up to 32v output n programmable load current monitor for end-of- charging-cycle notification (16-pin version) n dual function ic (lt1621) allows convenient integration of load and input current sensing n level-shifted current sense output for current mode pwm controllers n can be used for nicd, nimh, lead-acid and lithium- ion battery charging n greater than 96% efficiency possible in charger applications n high output currents possible: > 10a easily obtained d u escriptio the lt ? 1620 simplifies the design of high performance, controlled current battery charging circuits when used in conjunction with a current mode pwm controller ic. the LT1620 regulates average output current independent of input and output voltage variations. output current can be easily adjusted via a programming voltage applied to the LT1620s prog pin. most current mode pwm controllers have limited output voltage range because of common mode limitations on the current sense inputs. the LT1620 overcomes this restric- tion by providing a level-shifted current sense signal, allowing a 0v to 32v output voltage range. the 16-pin version of the LT1620 contains a program- mable low charging current flag output. this output flag can be used to signal when a li-ion battery charging cycle is nearing completion. the lt1621 incorporates two fully independent current control circuits for dual loop applications. u a o pp l ic at i ty p i ca l , ltc and lt are registered trademarks of linear technology corporation. battery charge current (a) 0 efficiency (%) 90 95 100 4 1620/21 ?ta02 85 80 75 1 2 3 5 v in = 24v v batt = 16v v batt = 12v v batt = 6v efficiency figure 1. low dropout, high current li-ion battery charger fb i th ltc1435
synchronous
buck
regulator avg
sense
LT1620ms8 v cc gnd 18 6 3 v batt i batt to 4a v in (v batt + 0.5v) to 32v LT1620/21 ?f01 in � in + i out prog
45 27 simplified schematic. see figure 2 for complete schematic 0.1 f 15.75k
1% 3k
1% 0.1 f sense � intv cc v in sw 27 h 0.025 22 f
35v
2 1.43m
0.1% 110k
0.1% 22 f
35v + + u s a o pp l ic at i n high current battery chargers n high output voltage dc/dc converters n constant current sources n overcurrent fault protectors
2 LT1620/lt1621 a u g w a w u w a r b s o lu t exi t i s power supply voltage: v cc ..........................C 0.3v to 7v programming voltage: prog, prog2 ............ C 0.3v to v cc + 0.3v (7v max) i out , sense, avg, avg2, mode voltage ................ C 0.3v to v cc + 0.3v (7v max) (referenced to ground) (note 1) sense amplifier input common mode ....... C 0.3v to 36v operating ambient temperature range commercial ............................................ 0 c to 70 c industrial ............................................ C 40 c to 85 c storage temperature range ................ C 65 c to 150 c lead temperature (soldering, 10 sec)................. 300 c wu u package / o rder i for atio order part number order part number q ja = 149 c/ w top view gn package
16-lead plastic ssop 1
2
3
4
5
6
7
8 16
15
14
13
12
11
10
9 sense
nc
i out
nc
gnd
mode
nc
in �
avg
nc
prog
prog2
avg2
v cc
nc
in + q ja = 149 c/ w top view gn package
16-lead plastic ssop 1
2
3
4
5
6
7
8 16
15
14
13
12
11
10
9 prog a
avg a
sense a
i out a
gnd b
in ? b
in + b
v cc b v cc a
in + a
in � a
gnd a
i out b
sense b
avg b
prog b LT1620cgn LT1620ign lt1621cgn lt1621ign 1
2
3
4 8
7
6
5 top view avg
prog
v cc
in + sense
i out
gnd
in ? ms8 package
8-lead plastic msop s8 package
8-lead plastic so order part number ms8 part marking bc consult factory for military grade parts. v in + = 16.8v, v cc = 5v, v iout = 2v, t a = 25 c unless otherwise noted. symbol parameter conditions min typ max units supply v cc 5v supply voltage l 4.5 5.0 5.5 v i cc dc active supply current sense = avg = prog = prog2 = v cc 2.8 3.8 ma LT1620gn 4.5v v cc 5.5v, in + C in C = 100mv l 4.0 ma dc active supply current sense = avg = prog = v cc 2.3 3.3 ma LT1620s8, LT1620ms8, 1/2 lt1621gn 4.5v v cc 5.5v, in + C in C = 100mv l 3.7 ma dc active supply current sense = avg = prog = v cc 1.3 1.9 ma LT1620s8, LT1620ms8, 1/2 lt1621gn 4.5v v cc 5.5v, in + C in C = 0mv l 2.1 ma current sense amplifier v cm input common mode range l 032v v id differential input voltage range 0v v cm 32v l 0 125 mv (in + C in C ) v ossense input offset - measured at 1 output v cc v cm 32v C 5 5 mv (v sense )v id = 80mv l C6 6 mv e lectr ic al c c hara terist ics LT1620cs8 LT1620is8 LT1620cms8 q ja = 250 c/w (ms) q ja = 120 c/w (s)
3 LT1620/lt1621 e lectr ic al c c hara terist ics in + = 16.8v, v cc = 5v, v iout = 2v, t a = 25 c unless otherwise noted. the l denotes specifications which apply over the full operating temperature range. note 1: absolute maximum ratings are those values beyond which the life of a device may be impaired. note 2: input bias currents are disabled when v cc is removed, even with common mode voltage present at in + , in C . symbol parameter conditions min typ max units current sense amplifier v osavg input offset - measured at 10 output v cc v cm 32v C 3 3 mv (v avg ) 35mv v id 125mv l C4 4 mv v cm = 0v, v id = 80mv l C10 15 mv v osavg2 input offset - measured at 20 output v cc v cm 32v C 3 3 mv (v avg2 ) 0v v id 35mv l C4 4 mv v sense no-load output offset 0v v cm 32v, v id = 0v, referenced to v cc l C 0.1 C 3 mv i b(in + , in C ) input bias current (sink) v cc v cm 32v (note 2) 200 270 400 m a l 185 430 m a input bias current (source) v cm = 0v (note 2) 4.0 5.25 ma l 5.50 ma transconductance amplifier g m amplifier transconductance 3000 3500 4000 m mho l 2200 4800 m mho a v amplifier voltage gain 1v v iout 3v 60 80 db v oliout i out saturation limit (sink) i iout = 50 m a l 0.05 0.15 v i iout = 200 m a l 0.10 0.30 v i iout = 1ma l 0.35 0.65 v v prog prog input range l v cc C 1.25 v cc v i bprog input bias current measured at prog pin 20 na v osprog input offset voltage i iout = 130 m aC77mv (v avg C v prog ) l C8 8 mv end-of-cycle comparator v prog2 prog2 input range l v cc C 2.5 v cc C 0.15 v v hyst input hysteresis measured at avg2 pin 15 mv i bprog2 input bias current measured at prog2 pin 20 na v olmode output logic low output (sink) i mode = 0.5ma l 0.1 0.5 v i mode = 10ma l 0.5 1.2 v pi fu ctio s u uu ensure continuity around zero inductor current. typical out- put is C3mv with differential input voltage (in + C in C ) = 0. avg: sense amplifier a v = C10 output and transconductance amplifier positive input. used as inte- gration node for average current control. integration time constant is calculated using 2.5k w typical output imped- ance. prog: transconductance amplifier negative input. pro- gram node for average current delivered to load during current mode operation. average current delivered to load imposes voltage differential at current sense amplifier v cc : 5v 10% power supply input. in + : sense amplifier positive input. typically connected to inductor side of current sense resistor. common mode voltage range is 0v to 32v. in C : sense amplifier negative input. typically connected to load side of current sense resistor. common mode voltage range is 0v to 32v. sense: sense amplifier a v = C 1 output. used as level- shifted output for pwm controller current sense input. the sense output is designed to have an inherent offset to
4 LT1620/lt1621 pi fu ctio s u uu input (across external sense resistor) equal to (v cc C v prog )/10. input voltage range is v cc to (v cc C 1.25v). avg2: sense amplifier a v = C 20 output and comparator positive input. used as integration node for end-of-cycle determination flag. integration time constant is calculated using 5k w typical output impedance. prog2: comparator negative input. program node for end-of-cycle determination typically used during voltage mode operation. the comparator threshold is reached when the current sense amplifier differential input voltage equals (v cc C v prog2 )/20. input voltage range is (v cc C 0.15v) to (v cc C 2.5v). gnd: ground reference. mode: comparator open collector output. output is logic low when magnitude of current sense amplifier differential input voltage is less than (v cc C v prog2 )/20. i out : transconductance amplifier output. in typical appli- cation, i out sinks current from current-setting node on companion pwm controller ic, facilitating current mode loop control. fu n ctio n al block diagra uu
w � + sense
amplifier v cc in + in � prog prog2* 500 2.5k � + sense avg avg2* i out mode* LT1620/21 ?fbd g m � + 5k *available in the LT1620gn only + � + � sense � sense + intv cc i th pwm
controller end-of-cycle
(active low) ( 1 gain) ( 10 gain) ( 20 gain) current
sense
resistor v id gnd 5v operatio n u current sense amplifier the current sense amplifier is a multiple output voltage amplifier with an operational input common mode range from 0v to 32v. the amplifier generates scaled output voltages at the sense, avg and avg2 (available in LT1620gn) pins. these output signal voltages are refer- enced to the v cc supply by pulling signal current through internal v cc referred resistors. (refer to the functional block diagram) the first output (sense) is a unity gain, level-shifted repre- sentation of the input signal (in + C in C ). in typical pwm/ charger type applications, this output is used to drive the current sense amplifier of the mated pwm controller ic. the other two outputs (avg and avg2) are internally connected to a transconductance amplifier and compara- tor, respectively. the avg output yields a gain of 10, and the avg2 output provides a gain of 20. these pins are
5 LT1620/lt1621 operatio n u used as integration nodes to facilitate averaging of the current sense amplifier signal. (note: filter capacitors on these pins should bypass to the v cc supply.) integration of these signals enables direct sensing and control of dc load current, eliminating the inclusion of ripple current in load determination. transconductance amplifier the transconductance amplifier converts the difference between the current programming input voltage (v prog ) and the average current sense output (v avg ) into a current at the amplifier output pin (i out ). the amplifier output is unidirectional and only sinks current. the amplifier is designed to operate at a typical output current of 130 m a (refer to the functional block diagram) with v avg = v prog . in typical pwm/charger type applica- tions, the i out current is used to servo the current control loop on the mated pwm controller ic to maintain a programmed load current. comparator the comparator circuit (available only in the LT1620gn) may be used as an end-of-cycle sensor in a li-ion battery charging system. the comparator detects when the charg- ing cur rent has fallen to a small value (typically 20% of the maximum charging current). the comparator drives an open collector output (mode) that pulls low when the v avg2 voltage is more positive than v prog2 (output current below the programmed threshold). applicatio n s i n for m atio n wu u u in figure 2, an LT1620ms8 is coupled with an ltc1435 switching regulator in a high performance lithium-ion battery charger application. the ltc1435 switching regu- lator delivers extremely low dropout as it is capable of approximately 99% duty cycle operation. no additional power supply voltage is required for the LT1620 in this application; it is powered directly from a 5v local supply generated by the ltc1435. the dc charge current control and high common mode current sense range of the LT1620 combine with the low dropout capabilities of the ltc1435 to make a 4-cell li-ion battery charger with over 96% efficiency, and only 0.5v input-to-output drop at 3a charging current. refer to the ltc1435 data sheet (available from the ltc factory) for additional information on ic func- tionality, performance and associated component selection. this LT1620/ltc1435 battery charger is designed to yield a 16.8v float voltage with a battery charge current of 3.2a. the v in supply can range from 17.3v to 28v (limited by the switch mosfets). the charger provides a constant 3.2a charge current until the battery voltage reaches the pro- grammed float voltage. once the float voltage is achieved, a precision voltage regulation loop takes control, allowing the charge current to fall as required to complete the battery charge cycle. r sense selection the LT1620 will operate throughout a current program- ming voltage (v prog ) range of 0v to C 1.25v (relative to v cc ), however, optimum accuracy will be obtained with a current setting program voltage of C 0.8v, corresponding to 80mv differential voltage across the current sense amplifier inputs. given the desired current requirement, selection of the load current sense resistor r sense is possible. for the desired 3.2a charge current; r sense = 80mv/3.2a or 0.025 w at the programmed 3.2a charge current, the sense resis- tor will dissipate (0.08v)(3.20a) = 0.256w, and must be rated accordingly. current sense the current sense inputs are connected on either side of the sense resistor with in + at the more positive potential, given average charging current flow. the sense resistor to in + , in C input paths should be connected using twisted pair or minimum pc trace spacing for noise immunity. keep lead lengths short and away from noise sources for best performance.
6 LT1620/lt1621 applicatio n s i n for m atio n wu u u tg c osc ltc1435 in � gnd i out sense in + LT1620ms8 5 6 7 8 4 3 v batt
16.8v v in
17.3v to 28v LT1620/21 ?f02 c11, 56pf c12, 0.1 f run/ss i th sfb sgnd v osense sense � sense + boost sw v in intv cc bg pgnd extv cc v cc prog avg 2 1 c10
100pf c9, 100pf r1
1k c14
1nf c13
0.033 f
x7r c17, 0.01 f r2
1.5m c4
0.1 f d2* d1* c5, 0.1 f si4412dy si4412dy l1
27 h c6
0.1 f c7
4.7 f r sense
0.025 c15
0.1 f c16
0.1 f r p1
3k
1% r p2
15.75k
1% c18
0.1 f r f2
110k
0.1% r f1
1.44m
0.1% c8, 100pf c3
22 f
35v c1
22 f
35v c2
22 f
35v run + + + + * d1, d2: central
semiconductor cmdsh-3 li-ion figure 2. LT1620/ltc1435 battery charger charge current programming output current delivered during current mode operation is determined through programming the voltage at the prog pin (v prog ). as mentioned above, optimum performance is obtained with (v cc C v prog ) = 0.8v. the LT1620 is biased with a precision 5v supply produced by the ltc1435, enabling use of a simple resistor divider from v cc to ground for a v prog reference. using the desired 2.5k w thevenin impedance at the prog pin, values of r p1 = 3k and r p2 = 15.75k are readily calculated. the prog pin should be decoupled to the v cc supply. different values of charging current can be obtained by changing the values of the resistors in the v prog setting divider to raise or lower the value of the programming voltage, or by changing the sense resistor to an appropri- ate value as described above. output float voltage the 3.2a charger circuit is designed for a 4-cell li-ion battery, or a battery float voltage of 16.8v. this voltage is programmed through a resistor divider feedback to the ltc1435 v osense pin, referencing its 1.19v bandgap voltage. resistor values are determined through the rela- tion: r f1 = (v batt C 1.19)/(1.19/r f2 ). setting r f2 = 110k yields r f1 = 1.44m. other decoupling concerns the application schematic shown in figure 2 employs several additional decoupling capacitors. due to the inher- ently noisy environment created in switching applications, decoupling of sensitive nodes is prudent. as noted in the schematic, decoupling capacitors are included on the current programming pin (prog) to the v cc rail and
7 LT1620/lt1621 applicatio n s i n for m atio n wu u u between the in + and in C inputs. effective decoupling of supply rails is also imperative in these types of circuits, as large current transients are the norm. power supply decoupling should be placed as close as possible to the ics, and each ic should have a dedicated capacitor. design equations sense resistor: r sense = v id /i max current limit programming voltage: v prog = v cc C [(10)(v id )] voltage feedback resistors: r f1 /r f2 = (v batt(float) C 1.19)/1.19 end-of-cycle flag application figure 3 illustrates additional connections using the LT1620gn, including the end-of-cycle (eoc) flag feature. the eoc threshold is used to notify the user when the required load current has fallen to a programmed value, usually a given percentage of maximum load. the end-of-cycle output (mode) is an open-collector pull- down; the circuit in figure 3 uses a 10k pull-up resistor on the mode pin, connected to v cc . the eoc flag threshold is determined through program- ming v prog2 . the magnitude of this threshold corre- sponds to 20 times the voltage across the sense amplifier inputs. as mentioned in the previous circuit discussion, the charging current level is set to correspond to a sense voltage of 80mv. the circuit in figure 3 uses a resistor divider to create a programming voltage (v cc Cv prog2 )of 0.5v. the mode flag will therefore trip when the charging current sense voltage has fallen to 0.5v/20 or 0.025v. thus, the end-of-cycle flag will trip when the charging current has been reduced to about 30% of the maximum value. input current sensing application monitoring the load placed on the v in supply of a charging system is achieved by placing a second current sense resistor in front of the charger v in input. this function is useful for systems that will overstress the input supply (wall adapter, etc.) if both battery charging and other system functions simultaneously require high currents. this allows use of input supply systems that are capable of driving full-load battery charging and full-load system requirements, but not simultaneously. if the input supply current exceeds a predetermined value due to a combina- tion of high battery charge current and external system demand, the input current sense function automatically figure 3. end-of-cycle flag implementation with LT1620gn figure 4. input current sensing application avg
prog
prog2
avg2
v cc
in +
sense
i out
v ee
mode
in �
LT1620gn LT1620/21 ?f03 connected as in figure 2 r1
5.5k r2
50k c2
3.3 f c1, 3.3 f r3
10k end-of-cycle
(active low) + + avg prog v cc in + sense LT1620ms8 1 2 3 4 8 7 i out gnd in � 6 5 v sw 7 v in 5 81 v fb 6 s/s 2 i fb 4 gnd gnd
tab 3 c1
1 f 22 f r p1
3k
1% r p2
12k
1% c2
1 f r1
0.033 l1b
10 h 22 f to
system load 4.7 f l1a
10 h 24 v c 0.22 f 0.1 f
x7r lt1513 run 5v 57k 6.4k 22 f
2 mbrs340 v batt = 12.3v 1620/21 ?f04 r sense
0.1 + + + li-ion
8 LT1620/lt1621 applicatio n s i n for m atio n wu u u reduces battery charging current until the external load subsides. in figure 4 the LT1620 is coupled with an lt1513 sepic battery charger ic to create an input overcurrent protected charger circuit. the programming voltage (v cc C v prog ) is set to 1.0v through a resistor divider (r p1 and r p2 ) from the 5v input supply to ground. in this configuration, if the input current drawn by the battery charger combined with the system load requirements exceeds a current limit threshold of 3a, the battery charger current will be reduced by the LT1620 such that the total input supply current is limited to 3a. refer to the lt1513 data sheet for additional information. programming accuracy considerations pwm controller error amp maximum source current in a typical battery charger application, the LT1620 con- trols charge current by servoing the error amplifier output pin of the associated pwm controller ic. current mode control is achieved when the LT1620 sinks all of the current available from the error amplifier. since the LT1620 has finite transconductance, the voltage required to gen- erate its necessary output current translates to input offset error. the LT1620 is designed for a typical i out sink current of 130 m a to help reduce this term. knowing the current source capability of the associated pwm control- ler in a given application will enable adjustment of the required programming voltage to accommodate the de- sired charge current. a plot of typical v prog voltage offset vs pwm source capability is shown in figure 5a. for example, the ltc1435 has a current source capability of about 75 m a. this translates to about C15mv of induced programming offset at v prog (the absolute voltage at the prog pin must be 15mv lower). v cc C v prog programmed voltage 1 0.8v the LT1620 sense amplifier circuit has an inherent input referred 3mv offset when in + C in C = 0v to insure closed- loop operation during light load conditions. this offset vs input voltage has a linear characteristic, crossing 0v as in + C in C = 80mv. the offset is translated to the avg output (times a factor of 10), and thus to the programming voltage v prog . a plot of typical v prog offset voltage vs in + C in C is pictured in figure 5b. for example, if the desired load current corresponds to 100mv across the sense resistor, the typical offset, at v prog is 7.5mv (the absolute voltage at the prog pin must be 7.5mv higher). this error term should be taken into consideration when using v id values significantly away from 80mv. v cc C v prog2 programmed voltage 1 1.6v (LT1620gn only) the offset term described above for v prog also affects the v prog2 programming voltage proportionally (times an addi- tional factor of 2). however, v prog2 voltage is typically set well below the zero offset point of 1.6v, so adjustment for this term is usually required. a plot of typical v prog2 offset voltage vs in + C in C is pictured in figure 5c. for example, setting the v prog2 voltage to correspond to in + C in C = 15mv typically requires an additional C 50mv offset (the absolute voltage at the prog2 pin must be 50mv lower). sense amplifier input common mode < (v cc C 0.5v) the LT1620 sense amplifier has additional input offset tolerance when the inputs are pulled significantly below the v cc supply. the amplifier can induce additional input referred offset of up to 11mv when the inputs are at 0v common-mode. this additional offset term reduces roughly linearly to zero when v cm is about v cc C 0.5v. in typical applications, this offset increases the charge current tol- erance for cold start conditions until v bat moves away from ground. the resulting output current shift is generally negative; however, this offset is not precisely controlled. precision operation should not be attempted with sense amplifier common mode inputs below v cc C 0.5v. input referred offset tolerance vs v cm is shown in figure 5d. v cc 1 5v the LT1620 sense amplifier induces a small additional offset when v cc moves away from 5v. this offset follows a linear characteristic and amounts to about 0.33mv (input-referred) over the recommended operating range of v cc , centered at 5v. this offset is translated to the avg and avg2 outputs (times factors of 10 and 20), and thus to the programming voltages. a plot of programming offsets vs v cc is shown in figure 5e.
9 LT1620/lt1621 applicatio n s i n for m atio n wu u u figure 5a. typical setpoint voltage (v prog ) changes slightly depending upon the amount of current sinked by the i out pin in + ?in � (v id ) input (mv) 0 v prog offset (mv) 20
10
0
�10
�20
�30
?0 60 100 LT1620/21 ?f05b 20 40 80 120 140 v cc = 5v
v cm = 16.8v
i out = 130 a figure 5b. typical setpoint voltage (v prog ) changes slightly depending upon the programmed differential input voltage (v id ) i out sink current ( a) 0 v prog offset (mv) 150 250 LT1620/21 ?f05a 50 100 200 40
30
20
10
0
�10
�20
�30
?0 v cc = 5v
v id = 80mv
v cm = 16.8v figure 5e. typical setpoint voltages for v prog and v prog2 change slightly depending upon the supply voltage (v cc ) v cc (v) 4.50 programming offset (mv) 0 5 5.50 LT1620/21 ?f05e ? ?0 4.75 5.00 5.25 10 v prog v prog2 v id = 80mv
v cm = 16.8mv
i out = 130 a in + ?in � (v id ) input (mv) 0 v prog2 offset (mv) 40
20
0
�20
�40
�60
?0 60 100 LT1620/21 ?f05c 20 40 80 120 140 v cc = 5v
v cm = 16.8v
i out = 130 a figure 5c. typical comparator threshold voltage (v prog2 ) changes slightly depending upon the programmed differential input voltage (v id ) figure 5d. sense amplifier input offset tolerence degrades for input common mode voltage (v cm ) below (v cc C 0.5v). this affects the sense, avg and avg2 amplifier outputs in + , in � common mode voltage (v cm ) (v) 0
8 10 12 35 LT1620/21 ?f05d 6 4 12 436 2 0 additional input referred offset (mv) 14
v cc = 5v
v id = 80mv
i out = 130 a
10 LT1620/lt1621 typical applicatio n s u high efficiency buck constant current source programmable constant current source avg prog v cc +in sense LT1620ms8 1 2 3 4 8 7 i out gnd ?n 6 5 0.1 f 10k
1% r prog 18k 0.1 f 1 f i prog 2n3904 22 vn2222lm out in gnd shdn shutdown 0.1 f 6v
to 28v 470 0.1 lt1121cs8-5 0.1 f i out
0a to 1a i out = (i prog )(10,000)
r prog = 40k for 1a output LT1620/21 ?ta01 81 53 d45vh10 + avg prog prog2 +in sense LT1620gn 1 3 5 16 14 i out gnd 13 9 avg2 6 mode 12 v cc 8 ?n 11 47k �0.047 f i out
0a to 1a LT1620/21 ?ta04 mbrs130t3 20k 0.1 f 10k
1% i prog r prog 10k 820 4.7k 1 f 33k 2n7002 2n7002 2n4403 2n4401
10k 4.7k
si9405
22 f
25v
tps 22 f
25v
tps 0.1 f 5v 6v to
15v
50 h
ctx50-4
0.05 i out = (i prog )(20,000)
r prog = 90k for 1a output + +
11 LT1620/lt1621 package descriptio u dimensions in inches (millimeters) unless otherwise noted. gn package 16-lead plastic ssop (narrow 0.150) (ltc dwg # 05-08-1641) gn16 (ssop) 0895 * dimension does not include mold flash. mold flash
shall not exceed 0.006" (0.152mm) per side
** dimension does not include interlead flash. interlead
flash shall not exceed 0.010" (0.254mm) per side 12 3 4 5 6 7 8 0.229 ?0.244
(5.817 ?6.198) 0.150 ?0.157**
(3.810 ?3.988) 16 15 14 13 0.189 ?0.196*
(4.801 ?4.978) 12 11 10 9 0.016 ?0.050
(0.406 ?1.270) 0.015 0.004
(0.38 0.10)
45 0 ?8 typ 0.0075 ?0.0098
(0.191 ?0.249) 0.053 ?0.069
(1.351 ?1.748) 0.008 ?0.012
(0.203 ?0.305) 0.004 ?0.009
(0.102 ?0.249) 0.025
(0.635)
bsc 1 2 3 4 0.150 ?0.157**
(3.810 ?3.988) 8 7 6 5 0.189 ?0.197*
(4.801 ?5.004) 0.228 ?0.244
(5.791 ?6.197) 0.016 ?0.050
0.406 ?1.270 0.010 ?0.020
(0.254 ?0.508) 45 0 ?8 typ 0.008 ?0.010
(0.203 ?0.254) so8 0996 0.053 ?0.069
(1.346 ?1.752) 0.014 ?0.019
(0.355 ?0.483) 0.004 ?0.010
(0.101 ?0.254) 0.050
(1.270)
typ dimension does not include mold flash. mold flash
shall not exceed 0.006" (0.152mm) per side
dimension does not include interlead flash. interlead
flash shall not exceed 0.010" (0.254mm) per side
*
** ms8 package 8-lead msop (ltc dwg # 05-08-1660) s8 package 8-lead plastic small outline (narrow 0.150) (ltc dwg # 05-08-1610) msop08 0596 * dimension does not include mold flash, protrusions or gate burrs. mold flash,
protrusions or gate burrs shall not exceed 0.006" (0.152mm) per side
** dimension does not include interlead flash or protrusions.
interlead flash or protrusions shall not exceed 0.006" (0.152mm) per side 12 3 4 0.192 0.004
(4.88 0.10) 8 7 6 5 0.118 0.004*
(3.00 0.10) 0.118 0.004**
(3.00 0.10) 0.021 0.004
(0.53 0.01) 0 ?6 typ seating
plane 0.007
(0.18) 0.040 0.006
(1.02 0.15) 0.012
(0.30)
0.006 0.004
(0.15 0.10) 0.025
(0.65)
typ information furnished by linear technology corporation is believed to be accurate and reliable. however, no responsibility is assumed for its use. linear technology corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
12 LT1620/lt1621 ? linear technology corporation 1996 16201f lt/gp 0197 7k ? printed in usa typical applicatio n u electronic circuit breaker avg prog v cc +in sense LT1620ms8 1 2 3 4 8 7 i out gnd ?n 6 5 4.7k 33k 100k 33k c delay 0.1 f 5v 0.033 5v at 1a
protected fault LT1620/21 ?ta03 1n4148 2n3904 1k 2n3904 si9434dy 100 typical dc trip at 1.6a
3a fault trips
in 2ms with c delay = 1.0 f related parts part number description comments ltc ? 1435 high efficiency low noise synchronous step-down 16-pin narrow so and ssop, v in 36v, programmable switching regulator constant frequency ltc1436/ltc1436-ppl/ high efficiency low noise synchronous step-down full-featured single controller, v in 36v, programmable ltc1437 switching regulator controllers constant frequency ltc1438/ltc1439 dual high efficiency low noise synchronous step-down full-featured dual controllers, v in 36v, programmable switching regulators constant frequency lt1510 1.5a constant-current/constant-voltage battery charger step-down charger for li-ion, nicd and nimh lt1511 3.0a constant-current/constant-voltage battery charger step-down charger that allows charging during computer with input current limiting operation and prevents wall-adapter overload lt1512 sepic constant-current/constant-voltage battery charger step-up/step-down charger for up to 1a charging current lt1513 sepic constant-current/constant-voltage battery charger step-up/step-down charger for up to 2a charging current ltc1538-aux dual high efficiency low noise synchronous step-down 5v standby in shutdown, v in 36v, programmable switching regulator constant frequency ltc1539 dual high efficiency low noise synchronous step-down 5v standby in shutdown, v in 36v, programmable switching regulator constant frequency linear technology corporation 1630 mccarthy blvd., milpitas, ca 95035-7417 l (408) 432-1900 fax: (408) 434-0507 l telex: 499-3977 l www.linear-tech.com
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