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1 lt1054/lt1054l switched-capacitor voltage converter with regulator s f ea t u re d u escriptio n available in space saving so-8 package n output current: 100ma (lt1054) 125ma (lt1054l) n low loss: 1.1v at 100ma n operating range:3.5v to 15v (lt1054) 3.5v to 7v (lt1054l) n reference and error amplifier for regulation n external shutdown n external oscillator synchronization n can be paralleled n pin compatible with the ltc ? 1044/ltc7660 the lt ? 1054 is a monolithic, bipolar, switched-capacitor voltage converter and regulator. the lt1054 provides higher output current than previously available converters with significantly lower voltage losses. an adaptive switch driver scheme optimizes efficiency over a wide range of output currents. total voltage loss at 100ma output current is typically 1.1v. this holds true over the full supply voltage range of 3.5v to 15v. quiescent current is typically 2.5ma. the lt1054 also provides regulation, a feature not previ- ously available in switched-capacitor voltage converters. by adding an external resistive divider a regulated output can be obtained. this output will be regulated against changes in both input voltage and output current. the lt1054 can also be shut down by grounding the feedback pin. supply current in shutdown is less than 100 m a. the internal oscillator of the lt1054 runs at a nominal frequency of 25khz. the oscillator pin can be used to adjust the switching frequency or to externally synchronize the lt1054. the lt1054 is pin compatible with previous converters such the ltc1044/ltc7660. output current (ma) 0 voltage loss (v) 1 2 50 1054 ta01 0 25 75 100 125 t j = 125 c
t j = 25 c
t j = 55 c lt1054 lt1054l 3.5v v in 15v (lt1054)
3.5v v in 7v (lt1054l)
c in = c out = 100 f
indicates guaranteed
test point , ltc and lt are registered trademarks of linear technology corporation. lt1054/lt1054l voltage loss n voltage inverter n voltage regulator n negative voltage doubler n positive voltage doubler u s a o pp l ic at i reference osc drive drive drive drive osc cap gnd cap + feedback/
shutdown + r r *external capacitors 2.5v 6 1 4 3 ? out lt1054 ?bd 5 2 8 7 q q v ref c in * v in c out * + + block diagra m w
2 lt1054/lt1054l a u g w a w u w a r b s o lu t exi t i s supply voltage (note 2) lt1054 ................................................................ 16v lt1054l ................................................................ 7v input voltage pin 1 ................................................. 0v v pin1 v + pin 3 (s package) ............................. 0v v pin3 v + pin 7 ............................................. 0v v pin7 v ref pin 13 (s package) ...................... 0v v pin13 v ref operating junction temperature range lt1054c/lt1054lc ............................. 0 c to 100 c lt1054i ........................................... C 40 c to 100 c lt1054m ......................................... C 55 c to 125 c maximum junction temperature (note 3) lt1054c/lt1054lc ........................................ 125 c lt1054i ............................................................ 125 c lt1054m ......................................................... 150 c storage temperature range h, j8, n8 and s8 packages ................ C55 c to 150 c s package ........................................ C 65 c to 150 c lead temperature (soldering, 10 sec)................. 300 c wu u package / o rder i for atio order part number lt1054ch lt1054mh t jmax = 150 c, q ja = 150 c, q jc = 45 c/w top view osc v + fb/shdn v ref v out gnd cap case is v out cap + 8 7 6 5 3 2 1 4 h package 8-lead to-5 metal can t jmax = 125 c, q ja = 120 c/w order part number t jmax = 125 c, q ja = 150 c/w 1 2 3 4 8 7 6 5 top view fb/shdn cap + gnd cap v + osc v ref v out n8 package 8-lead plastic dip j8 package 8-lead ceramic dip t jmax = 150 c, q ja = 100 c/ w (j8) t jmax = 125 c, q ja = 130 c/ w (n8) 1 2 3 4 8 7 6 5 top view v + osc v ref v out fb/shdn cap + gnd cap s8 package 8-lead plastic so see regulation and capacitor selection sections in the applications information for important information on the s8 device (note 6) order part number lt1054cs8 lt1054lcs8 s8 part marking 1054 1054l (note 1) order part number lt1054csw lt1054isw lt1054cj8 lt1054cn8 LT1054IN8 lt1054mj8 1 2 3 4 5 6 7 8 top view sw package 16-lead plastic so 16 15 14 13 12 11 10 9 nc nc fb/shdn cap + gnd cap nc nc nc nc v + osc v ref v out nc nc ot recomme ded for ew desig s u u u u ww 3 lt1054/lt1054l e lectr ic al c c hara terist ics parameter conditions min typ max units supply current i load = 0ma lt1054: v in = 3.5v l 2.5 4.0 ma v in = 15v l 3.0 5.0 ma lt1054l: v in = 3.5v l 2.5 4.0 ma v in = 7v l 3.0 5.0 ma supply voltage range lt1054 l 3.5 15 v lt1054l l 3.5 7 v voltage loss (v in C ? v out ? )c in = c out = 100 m f tantalum (note 4) i out = 10ma l 0.35 0.55 v i out = 100ma l 1.10 1.60 v i out = 125ma (lt1054l) l 1.35 1.75 v output resistance d i out = 10ma to 100ma (note 5) l 10 15 w oscillator frequency lt1054: 3.5v v in 15v l 15 25 35 khz lt1054l: 3.5v v in 7v l 15 25 35 khz reference voltage i ref = 60 m a, t j = 25 c 2.35 2.50 2.65 v l 2.25 2.75 v regulated voltage v in = 7v, t j = 25 c, r l = 500 w (note 6) C 4.70 C 5.00 C 5.20 v line regulation lt1054: 7v v in 12v, r l = 500 w (note 6) l 525 mv load regulation v in = 7v, 100 w r l 500 w (note 6) l 10 50 mv maximum switch current 300 ma supply current in shutdown v pin1 = 0v l 100 200 m a (note 7) note 5: output resistance is defined as the slope of the curve, ( d v out vs d i out ), for output currents of 10ma to 100ma. this represents the linear portion of the curve. the incremental slope of the curve will be higher at currents < 10ma due to the characteristics of the switch transistors. note 6: all regulation specifications are for a device connected as a positive-to-negative converter/regulator with r1 = 20k, r2 = 102.5k, c1 = 0.002 m f, (c1 = 0.05 m f s package) c in = 10 m f tantalum, c out = 100 m f tantalum. note 7: the s8 package uses a different die than the h, j8, n8 and s packages. the s8 device will meet all the existing data sheet parameters. see regulation and capacitor selection in the applications information section for differences in application requirements. 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: the absolute maximum supply voltage rating of 16v is for unregulated circuits using lt1054. for regulation mode circuits using lt1054 with v out 15v at pin 5 (pin 11 on s package), this rating may be increased to 20v. the absolute maximum supply voltage for lt1054l is 7v. note 3: the devices are guaranteed by design to be functional up to the absolute maximum junction temperature. note 4: for voltage loss tests, the device is connected as a voltage inverter, with pins 1, 6, and 7 (3, 12, and 13 s package) unconnected. the voltage losses may be higher in other configurations. 4 lt1054/lt1054l cc hara terist ics uw a t y p i ca lper f o r c e shutdown threshold temperature (?) ?0 ?0 15 frequency (khz) 25 35 0 50 75 lt1054 ?tpc03 ?5 25 100 125 v in = 15v v in = 3.5v input voltage (v) 0 0 supply current (ma) 1 2 3 4 5 i l = 0 5 10 15 lt1054 ?tpc02 supply current in shutdown input voltage (v) 0 0 quiescent current ( m a) 20 40 60 80 120 5 10 15 lt1054 ?tpc04 100 v pin1 = 0v output current (ma) 0 0 average input current (ma) 20 60 80 100 140 lt1050 ?tpc05 40 120 40 100 20 60 80 input capacitance ( m f) 0 0 voltage loss (v) 0.2 0.6 0.8 1.0 1.4 10 50 70 lt1054 ?tpc06 0.4 1.2 40 90 100 20 30 60 80 inverter configuration c out = 100 m f tantalum f osc = 25khz i out = 100ma i out = 50ma i out = 10ma oscillator frequency (khz) 1 0 voltage loss (v) 1 2 10 100 lt1054 ?tpc07 inverter configuration c in = 10 m f tantalum c out = 100 m f tantalum i out = 100ma i out = 50ma i out = 10ma oscillator frequency (khz) 1 0 voltage loss (v) 1 2 10 100 lt1054 ?tpc08 inverter configuration c in = 100 m f tantalum c out = 100 m f tantalum i out = 100ma i out = 50ma i out = 10ma temperature (?c) ?0 shutdown threshold (v) 0.4 0.5 0.6 25 75 lt1054 ?tpc01 0.3 0.2 ?5 0 50 100 125 0.1 0 v pin1 supply current oscillator frequency average input current output voltage loss output voltage loss output voltage loss 5 lt1054/lt1054l cc hara terist ics uw a t y p i ca lper f o r c e temperature (?) ?0 100 reference voltage change (mv) ?0 ?0 ?0 0 100 40 0 50 75 lt1054 ?tpc10 ?0 60 80 20 ?5 25 100 125 v ref at 0 = 2.500v temperature (?) ?0 12.6 output voltage (v) 12.4 12.0 11.8 11.6 4.7 5.0 0 50 75 lt1054 ?tpc09 12.2 4.9 4.8 5.1 ?5 25 100 125 regulated output voltage reference voltage temperature coefficient pi n fu n ctio n s uuu pin 1 is also the inverting input of the lt1054s error amplifier and as such can be used to obtain a regulated output voltage. cap + /cap C (pin 2/pin 4): pin 2, the positive side of the input capacitor (c in ), is alternately driven between v + and ground. when driven to v + , pin 2 sources current from v + . when driven to ground pin 2 sinks current to ground. pin 4, the negative side of the input capacitor, is driven alter- nately between ground the v out . when driven to ground, pin 4 sinks current to ground. when driven to v out pin 4 sources current from c out . in all cases current flow in the switches is unidirectional as should be expected using bipolar switches. v out (pin 5): in addition to being the output pin this pin is also tied to the substrate of the device. special care must be taken in lt1054 circuits to avoid pulling this pin positive with respect to any of the other pins . pulling pin 5 positive with respect to pin 3 (gnd) will forward bias the substrate diode which will prevent the device from starting. this condition can occur when the output load driven by the lt1054 is referred to its positive supply (or to some other positive voltage). note that most op amps present just such a load since their supply currents flow from their v + terminals to their v C terminals. to prevent start-up prob- lems with this type of load an external transistor must be added as shown in figure 1. this will prevent v out (pin 5) fb/shdn (pin 1): feedback/shutdown pin. this pin has two functions. pulling pin 1 below the shutdown threshold ( ? 0.45v) puts the device into shutdown. in shutdown the reference/regulator is turned off and switching stops. the switches are set such that both c in and c out are dis- charged through the output load. quiescent current in shutdown drops to approximately 100 m a (see typical performance characteristics). any open-collector gate can be used to put the lt1054 into shutdown. for normal (unregulated) operation the device will start back up when the external gate is shut off. in lt1054 circuits that use the regulation feature, the external resistor divider can provide enough pull-down to keep the device in shutdown until the output capacitor (c out ) has fully discharged. for most applications where the lt1054 would be run intermittently, this does not present a problem because the discharge time of the output capacitor will be short compared to the off- time of the device. in applications where the device has to start up before the output capacitor (c out ) has fully dis- charged, a restart pulse must be applied to pin 1 of the lt1054. using the circuit of figure 5, the restart signal can be either a pulse (t p > 100 m s) or a logic high. diode coupling the restart signal into pin 1 will allow the output voltage to come up and regulate without overshoot. the resistor divider r3/r4 in figure 5 should be chosen to provide a signal level at pin 1 of 0.7v to 1.1v. 6 lt1054/lt1054l pi n fu n ctio n s uuu from being pulled above the ground pin (pin 3) during start-up. any small, general purpose transistor such as 2n2222 or 2n2219 can be used. r x should be chosen to provide enough base drive to the external transistor so that it is saturated under nominal output voltage and maximum output current conditions. in some cases an n-channel enhancement mode mosfet can be used in place of the transistor. r x ( | v out | ) b i out + load c in c out lt1054 ?f01 i l v + r x lt1054 fb/shdn cap + gnd cap v + osc v ref v out i q i out + + v ref (pin 6): reference output. this pin provides a 2.5v reference point for use in lt1054-based regulator circuits. the temperature coefficient of the reference voltage has been adjusted so that the temperature coefficient of the regulated output voltage is close to zero. this requires the reference output to have a positive temperature coefficient as can be seen in the typical performance curves. this nonzero drift is necessary to offset a drift term inherent in the internal reference divider and comparator network tied to the feedback pin. the overall result of these drift terms is a regulated output which has a slight positive tempera- ture coefficient at output voltages below 5v and a slight negative tc at output voltages above 5v. reference output current should be limited, for regulator feedback networks, to approximately 60 m a. the reference pin will draw ? 100 m a when shorted to ground and will not affect the internal reference/regulator, so that this pin can also be used as a pull-up for lt1054 circuits that require synchro- nization. osc (pin 7): oscillator pin. this pin can be used to raise or lower the oscillator frequency or to synchronize the device to an external clock. internally pin 7 is connected to the oscillator timing capacitor (c t ? 150pf) which is alternately charged and discharged by current sources of 7 m a so that the duty cycle is ? 50%. the lt1054 oscillator is designed to run in the frequency band where switching losses are minimized. however the frequency can be raised, lowered, or synchronized to an external system clock if necessary. the frequency can be lowered by adding an external capacitor (c1, figure 2) from pin 7 to ground. this will increase the charge and discharge times which lowers the oscillator frequency. the frequency can be increased by adding an external capacitor (c2, figure 2, in the range of 5pf to 20pf) from pin 2 to pin 7. this capacitor will couple charge into c t at the switch transitions, which will shorten the charge and discharge time, raising the oscillator fre- quency. synchronization can be accomplished by adding an external resistive pull-up from pin 7 to the reference pin (pin 6). a 20k pull-up is recommended. an open collector gate or an npn transistor can then be used to drive the oscillator pin at the external clock frequency as shown in figure 2. pulling up pin 7 to an external voltage is not recommended . for circuits that require both fre- quency synchronization and regulation, an external refer- ence can be used as the reference point for the top of the r1/r2 divider allowing pin 6 to be used as a pull-up point for pin 7. figure 1 v + (pin 8): input supply. the lt1054 alternately charges c in to the input voltage when c in is switched in parallel with the input supply and then transfers charge to c out when c in is switched in parallel with c out . switching occurs at v in c out c in c2 c1 lt1054 ?f02 lt1054 fb/shdn cap + gnd cap v + osc v ref v out + + figure 2 7 lt1054/lt1054l the oscillator frequency. during the time that c in is charg- ing, the peak supply current will be approximately equal to 2.2 times the output current. during the time that c in is delivering charge to c out the supply current drops to approximately 0.2 times the output current. an input supply bypass capacitor will supply part of the peak input current drawn by the lt1054 and average out the current drawn from the supply. a minimum input supply bypass capacitor of 2 m f, preferably tantalum or some other low esr type is recommended. a larger capacitor may be desirable in some cases, for example, when the actual input supply is connected to the lt1054 through long leads, or when the pulse current drawn by the lt1054 might affect other circuitry through supply coupling. pi n fu n ctio n s uuu applicatio n s i n for m atio n wu u u theory of operation to understand the theory of operation of the lt1054, a review of a basic switched-capacitor building block is helpful. in figure 3 when the switch is in the left position, capacitor c1 will charge to voltage v1. the total charge on c1 will be q1 = c1v1. the switch then moves to the right, discharging c1 to voltage v2. after this discharge time the charge on c1 is q2 = c1v2. note that charge has been transferred from the source v1 to the output v2. the amount of charge transferred is: d q = q1 C q2 = c1(v1 C v2) if the switch is cycled f times per second, the charge transfer per unit time (i.e., current) is: i = (f)( d q) = (f)[c1(v1 C v2)] to obtain an equivalent resistance for the switched-capaci- tor network we can rewrite this equation in terms of voltage and impedance equivalence: i = = v1 ?v2 (1/fc1) v1 ?v2 r equiv a new variable r equiv is defined such that r equiv = 1/fc1. thus the equivalent circuit for the switched-capacitor network is as shown in figure 4. the lt1054 has the same switching action as the basic switched-capacitor building block. even though this simplification doesnt include finite switch on-resistance and output voltage ripple, it provides an intuitive feel for how the device works. these simplified circuits explain voltage loss as a function of frequency (see typical performance characteristics). as frequency is decreased, the output impedance will eventu- f c1 c2 r l v2 lt1054 ?f03 v1 figure 3. switched-capacitor building block c2 r l r equiv r equiv = v2 lt1054 ?f04 v1 1 fc1 figure 4. switched-capacitor equivalent circuit ally be dominated by the 1/fc1 term and voltage losses will rise. note that losses also rise as frequency increases. this is caused by internal switching losses which occur due to some finite charge being lost on each switching cycle. this charge loss per-unit-cycle, when multiplied by the switch- ing frequency, becomes a current loss. at high frequency this loss becomes significant and voltage losses again rise. the oscillator of the lt1054 is designed to run in the frequency band where voltage losses are at a minimum. regulation t he error amplifier of the lt1054 servos the drive to the pnp switch to control the voltage across the input capaci- tor (c in ) which in turn will determine the output voltage. using the reference and error amplifier of the lt1054, an external resistive divider is all that is needed to set the regulated output voltage. figure 5 shows the basic regu- lator configuration and the formula for calculating the appropriate resistor values. r1 should be chosen to be 8 lt1054/lt1054l applicatio n s i n for m atio n wu u u voltage. for the basic configuration, | v out | referred to the ground pin of the lt1054 must be less than the total of the supply voltage minus the voltage loss due to the switches. the voltage loss versus output current due to the switches can be found in typical performance characteristics. other configurations such as the negative doubler can provide higher output voltages at reduced output currents (see typical applications). capacitor selection for unregulated circuits the nominal values of c in and c out should be equal. for regulated circuits see the section on regulation. while the exact values of c in and c out are noncritical, good quality, low esr capacitors such as solid tantalum are necessary to minimize voltage losses at high currents. for c in the effect of the esr of the capacitor will be multiplied by four due to the fact that switch currents are approximately two times higher than output current and losses will occur on both the charge and discharge cycle. this means that using a capacitor with 1 w of esr for c in will have the same effect as increasing the output imped- ance of the lt1054 by 4 w . this represents a significant increase in the voltage losses. for c out the affect of esr is less dramatic. c out is alternately charged and discharged at a current approximately equal to the output current and the esr of the capacitor will cause a step function to occur in the output ripple at the switch transitions. this step function will degrade the output regulation for changes in output load current and should be avoided. realizing that large value tantalum capacitors can be expensive, a tech- nique that can be used is to parallel a smaller tantalum capacitor with a large aluminum electrolytic capacitor to gain both low esr and reasonable cost. where physical size is a concern some of the newer chip type surface mount tantalum capacitors can be used. these capacitors are normally rated at working voltages in the 10v to 20v range and exhibit very low esr (in the range of 0.1 w ). output ripple the peak-to-peak output ripple is determined by the value of the output capacitor and the output current. peak-to- peak output ripple may be approximated by the formula: dv = i out 2fc out r4 restart shutdown c1 r2 c in 10 f tantalum c out 100 f tantalum v out lt1054 ?f05 v in r1 2.2 f r3 r2 r1 = ? + 1 where v ref = 2.5v nominal *choose the closest 1% value for example: to get v out = 5v referred to the ground pin of the lt1054, choose r1 = 20k, then | v out | ) ) v ref 2 ?40mv r2 = 20k = 102.6k* + 1 | ?v | ) ) 2.5v 2 ?40mv ) ) + 1 | v out | 1.21v lt1054 fb/shdn cap + gnd cap v + osc v ref v out + + + figure 5 20k or greater because the reference output current is limited to ? 100 m a. r2 should be chosen to be in the range of 100k to 300k. for optimum results the ratio of c in /c out is recommended to be 1/10. c1, required for good load regulation at light load currents, should be 0.002 m f for all output voltages. a new die layout was required to fit into the physical dimensions of the s8 package. although the new die of the lt1054cs8 will meet all the specifications of the existing lt1054 data sheet, subtle differences in the layout of the new die require consideration in some application cir- cuits. in regulating mode circuits using the 1054cs8 the nominal values of the capacitors, c in and c out , must be approximately equal for proper operation at elevated junction temperatures. this is different from the earlier part. mismatches within normal production tolerances for the capacitors are acceptable. making the nominal capacitor values equal will ensure proper operation at elevated junction temperatures at the cost of a small degradation in the transient response of regulator cir- cuits. for unregulated circuits the values of c in and c out are normally equal for all packages. for s8 applications assistance in unusual applications circuits, please consult the factory. it can be seen from the circuit block diagram that the maximum regulated output voltage is limited by the supply 9 lt1054/lt1054l applicatio n s i n for m atio n wu u u r x = v x /(4.4 i out ) where v x ? v in C [(lt1054 voltage loss)(1.3) + | v out | ] and i out = maximum required output current. the factor of 1.3 will allow some operating margin for the lt1054. for example: assume a 12v to C 5v converter at 100ma output current. first calculate the power dissipation with- out an external resistor: p = (12v C | C5v | )(100ma) + (12v)(100ma)(0.2) p = 700mw + 240mw = 940mw at q ja of 130 c/w for a commercial plastic device this would cause a junction temperature rise of 122 c so that the device would exceed the maximum junction tempera- ture at an ambient temperature of 25 c. now calculate the power dissipation with an external resistor (r x ). first find how much voltage can be dropped across r x . the maxi- mum voltage loss of the lt1054 in the standard regulator configuration at 100ma output current is 1.6v, so v x = 12v C [(1.6v)(1.3) + | C5v | ] = 4.9v and r x = 4.9v/(4.4)(100ma) = 11 w this resistor will reduce the power dissipated by the lt1054 by (4.9v)(100ma) = 490mw. the total power dissipated by the lt1054 would then be (940mw C 490mw) = 450mw. the junction temperature rise would now be only 58 c. although commercial devices are guaranteed to be functional up to a junction temperature of 125 c, the specifications are only guaranteed up to a junction temperature of 100 c, so ideally you should limit the junction temperature to 100 c. for the above example this would mean limiting the ambient temperature to 42 c. other steps can be taken to allow higher ambient tempera- tures. the thermal resistance numbers for the lt1054 packages represent worst case numbers with no heat sinking and still air. small clip-on type heat sinks can be used to lower the thermal resistance of the lt1054 pack- age. in some systems there may be some available airflow which will help to lower the thermal resistance. wide pc board traces from the lt1054 leads can also help to remove heat from the device. this is especially true for plastic packages. where dv = peak-to-peak ripple and f = oscillator frequency. for output capacitors with significant esr a second term must be added to account for the voltage step at the switch transitions. this step is approximately equal to: (2i out )(esr of c out ) power dissipation the power dissipation of any lt1054 circuit must be limited such that the junction temperature of the device does not exceed the maximum junction temperature rat- ings. the total power dissipation must be calculated from two components, the power loss due to voltage drops in the switches and the power loss due to drive current losses. the total power dissipated by the lt1054 can be calculated from: p ? (v in C | v out | )(i out ) + (v in )(i out )(0.2) where both v in and v out are referred to the ground pin (pin 3) of the lt1054. for lt1054 regulator circuits, the power dissipation will be equivalent to that of a linear regulator. due to the limited power handling capability of the lt1054 packages, the user will have to limit output current require- ments or take steps to dissipate some power external to the lt1054 for large input/output differentials. this can be accomplished by placing a resistor in series with c in as shown in figure 6. a portion of the input voltage will then be dropped across this resistor without affecting the output regulation. because switch current is approximately 2.2 times the output current and the resistor will cause a voltage drop when c in is both charging and discharging, the resistor should be chosen as: c1 r2 c in c out v out lt1054 ?f06 v in r1 rx lt1054 fb/shdn cap + gnd cap v + osc v ref v out + + figure 6 10 lt1054/lt1054l typical applicatio n s n u basic voltage inverter positive doubler negative voltage doubler 100ma regulating negative doubler 1n4002 hp5082-2810 v in 3.5 to 15v 20k 1n4002 0.002 f lt1054 ?tao6 2.2 f r1 40k v out set pin 2 lt1054 #1 ? out i out @ 100ma max r2 500k 1n4002 1n4002 1n4002 , refer to figure 5 v in = 3.5 to 15v v out max ? ?v in + [1054 voltage loss + 2(v diode )] r2 r1 == + 1 | v out | ) ) v ref 2 ?40mv ) ) + 1 | v out | 1.21v 10 f10 f 100 f + + + 10 f + 10 f 10 f + + + 10 f + lt1054 #1 fb/shdn cap + gnd cap v + osc v ref v out lt1054 #2 fb/shdn cap + gnd cap v + osc v ref v out basic voltage inverter/regulator 0.002 f r2 10 f 100 f refer to figure 5 2 f v out lt1054 ?ta03 v in r1 r2 r1 == + 1 | v out | ) ) v ref 2 ?40mv ) ) + 1 , | v out | 1.21v lt1054 fb/shdn cap + gnd cap v + osc v ref v out + + + 100 f v in ? out lt1054 ?tao2 lt1054 fb/shdn cap + gnd cap v + osc v ref v out 2 f 100 f + + + 2 f 100 f v in = 3.5v to 15v v out = 2v in + (lt1054 voltage loss) + (q x saturation voltage) *see figure 3 v in v in v out lt1054 ?tao4 r x * + 100 f + + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out q x * 1n4001 v in = 3.5v to 15v v out ? 2v in ?(v l + 2v diode ) v l = lt1054 voltage loss v in 3.5v to 15v lt1054 ?tao5 1n4001 v out 50ma + 100 f 2 f 10 f + + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out 11 lt1054/lt1054l typical applicatio n s n u 5v to 12v converter bipolar supply doubler 20k 1n914 1n914 v in = 5v to pin 4 lt1054 #1 v out ? ?2v i out = 25ma v out ? 12v i out = 25ma lt1054 ?tao8 1k 2n2219 10 f 100 f 10 f 10 f 100 f 5 f 100 f 5 f + + + + + + + + lt1054 #2 fb/shdn cap + gnd cap v + osc v ref v out lt1054 #1 fb/shdn cap + gnd cap v + osc v ref v out v in 3.5v to 15v ? out lt1054 ?tao7 +v out + + = 1n4001 v in = 3.5v to 15v +v out ? 2v in ?(v l + 2v diode ) ? out ? ?v in + (v l + 2v diode ) v l = lt1054 voltage loss 100 f 10 f 10 f 10 f 100 f 100 f + + + + + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out 1 f 5v 1 2 3 8 200k 3k 100 f tantalum lt1054 ?tao9 0.022 f + 2n2222 a = 125 for 0v to 3v out from full-scale bridge output of 24mv 100k 100k 10k zero trim 5k gain trim 10k 10k 5v 40 301k 1m a1 1/2 lt1013 5k 6 5 4 7 10k 2n2907 input ttl or cmos low for on 350 + a2 1/2 lt1013 10 f + + 10 f + lt1054 fb/shdn cap + gnd cap v + osc v ref v out strain gauge bridge signal conditioner 12 lt1054/lt1054l typical applicatio n s n u 3.5v to 5v regulator regulating 200ma, 12v to C 5v converter digitally programmable negative supply 20k v out = v in (programmed) 20k 15v lt1004-2.5 2.5v lt1054 ?ta12 ad558 16 11 14 digital input 13 12 10 f 5 f + 100 f + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out 0.002 f hp5082-2810 v out = ?v i out = 0ma to 200ma 12v r1 39.2k r2 200k 20k 10 1/2w lt1054 ?ta11 10 1/2w 10 f 5 f 200 f 10 f + + + + lt1054 #1 fb/shdn cap + gnd cap v + osc v ref v out lt1054 #2 fb/shdn cap + gnd cap v + osc v ref v out refer to figure 5 r2 r1 == + 1 | v out | ) ) v ref 2 ?40mv ) ) + 1 , | v out | 1.21v 5 f 100 f 20k 1n914 r1 20k 1n914 v in = 3.5v to 5.5v v out = 5v i out(max) = 50ma 1n914 1n5817 v in 3.5v to 5.5v lt1054 ?ta10 ltc1044 1 2 3 4 8 7 6 5 1 f 1 f 0.002 f r2 125k 3k 1n914 r2 125k 2n2219 v out = 5v + 10 f + + + + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out 13 lt1054/lt1054l dimensions in inches (millimeters) unless otherwise noted. package descriptio n u h package 8-lead to-5 metal can (0.200 pcd) (ltc dwg # 05-08-1320) j8 1197 0.014 ?0.026 (0.360 ?0.660) 0.200 (5.080) max 0.015 ?0.060 (0.381 ?1.524) 0.125 3.175 min 0.100 0.010 (2.540 0.254) 0.300 bsc (0.762 bsc) 0.008 ?0.018 (0.203 ?0.457) 0 ?15 0.005 (0.127) min 0.405 (10.287) max 0.220 ?0.310 (5.588 ?7.874) 12 3 4 87 65 0.025 (0.635) rad typ 0.045 ?0.068 (1.143 ?1.727) full lead option 0.023 ?0.045 (0.584 ?1.143) half lead option corner leads option (4 plcs) 0.045 ?0.068 (1.143 ?1.727) note: lead dimensions apply to solder dip/plate or tin plate leads j8 package 8-lead cerdip (narrow 0.300, hermetic) (ltc dwg # 05-08-1110) 0.050 (1.270) max 0.016 ?0.021** (0.406 ?0.533) 0.010 ?0.045* (0.254 ?1.143) seating plane 0.040 (1.016) max 0.165 ?0.185 (4.191 ?4.699) gauge plane reference plane 0.500 ?0.750 (12.700 ?19.050) 0.305 ?0.335 (7.747 ?8.509) 0.335 ?0.370 (8.509 ?9.398) dia 0.200 (5.080) typ 0.027 ?0.045 (0.686 ?1.143) 0.028 ?0.034 (0.711 ?0.864) 0.110 ?0.160 (2.794 ?4.064) insulating standoff 45 typ h8(to-5) 0.200 pcd 1197 lead diameter is uncontrolled between the reference plane and 0.045" below the reference plane for solder dip lead finish, lead diameter is 0.016 ?0.024 (0.406 ?0.610) * ** pin 1 14 lt1054/lt1054l dimensions in inches (millimeters) unless otherwise noted. package descriptio n u n8 1197 0.100 0.010 (2.540 0.254) 0.065 (1.651) typ 0.045 ?0.065 (1.143 ?1.651) 0.130 0.005 (3.302 0.127) 0.020 (0.508) min 0.018 0.003 (0.457 0.076) 0.125 (3.175) min 12 3 4 87 6 5 0.255 0.015* (6.477 0.381) 0.400* (10.160) max 0.009 ?0.015 (0.229 ?0.381) 0.300 ?0.325 (7.620 ?8.255) 0.325 +0.035 0.015 +0.889 0.381 8.255 () *these dimensions do not include mold flash or protrusions. mold flash or protrusions shall not exceed 0.010 inch (0.254mm) n8 package 8-lead pdip (narrow 0.300) (ltc dwg # 05-08-1510) s8 package 8-lead plastic small outline (narrow 0.150) (ltc dwg # 05-08-1610) 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 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) 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) 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 * ** 15 lt1054/lt1054l dimensions in inches (millimeters) unless otherwise noted. package descriptio n u 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 represen- tation that the interconnection of its circuits as described herein will not infringe on existing patent rights. s16 (wide) 0396 note 1 0.398 ?0.413* (10.109 ?10.490) 16 15 14 13 12 11 10 9 1 23 4 5 6 78 0.394 ?0.419 (10.007 ?10.643) 0.037 ?0.045 (0.940 ?1.143) 0.004 ?0.012 (0.102 ?0.305) 0.093 ?0.104 (2.362 ?2.642) 0.050 (1.270) typ 0.014 ?0.019 (0.356 ?0.482) typ 0 ?8 typ note 1 0.009 ?0.013 (0.229 ?0.330) 0.016 ?0.050 (0.406 ?1.270) 0.291 ?0.299** (7.391 ?7.595) 45 0.010 ?0.029 (0.254 ?0.737) note: 1. pin 1 ident, notch on top and cavities on the bottom of packages are the manufacturing options. the part may be supplied with or without any of the options 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 * ** sw package 16-lead plastic small outline (wide 0.300) (ltc dwg # 05-08-1620) 16 lt1054/lt1054l ? linear technology corporation 1987 1054ld lt/tp 1298 2k rev d ? printed in usa typical applicatio n s n u negative doubler with regulator 2 f v in 3.5v to 15v 100 f r2 1m 1n4001 1n4001 lt1054 ?ta14 100 f 0.002 f ? out v in = 3.5v to 15v v out(max) ? ?v in + (v l + 2v diode ) v l = lt1054 voltage loss , refer to figure 5 r2 r1 == + 1 | v out | ) ) v ref 2 ?40mv ) ) + 1 | v out | 1.21v 10 f + + + + 10 f + lt1054 fb/shdn cap + gnd cap v + osc v ref v out r1, 20k 0.03 f v in = 5v 50k 1n5817 1n5817 lt1054 ?ta13 + 10k 10k 10k 5.5k 2.5k 0.1 f 5v lt1006 100 f v out 8v 50ma 2 f 10 f + + + lt1054 fb/shdn cap + gnd cap v + osc v ref v out positive doubler with regulation linear technology corporation 1630 mccarthy blvd., milpitas, ca 95035-7417 (408) 432-1900 l fax: (408) 434-0507 l www.linear-tech.com related parts part number description comments ltc1144 switched-capacitor voltage converter wide input voltage range, 2v to 18v ltc1514/ltc1515 step-up/step-down switched capacitor dc/dc converters regulated 5v doublers lt1611 micropower inverting dc/dc converter 150ma output lt1614 micropower inverting dc/dc converter 250ma output the typical applications circuits were verified using the standard lt1054. for s8 applications assistance in any of the unusual applications circuits please consult the factory |
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