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| i o i r v r v o rated output power = v r i r pi-3924-011706 lnk562-564 linkswitch-lp energy ef � cient off-line switcher ic for linear transformer replacement figure 1. typical application ? not a simpli � ed circuit (a) and output characteristic envelope (b). product highlights lowest system cost and advanced safety features ? lowest component count switcher ? very tight parameter tolerances using proprietary ic trimming technology and transformer construction techniques enable clampless ?designs ? decreases component count/system cost and increases ef � ciency ? meets industry standard requirements for thermal overload protection ? eliminates the thermal fuse used with linear transformers or additional components in rcc designs ? frequency jittering greatly reduces emi ? enables low cost input � lter con � guration ? meets hv creepage requirements between drain and all other pins, both on the pcb and at the package ? proprietary e-shield ? transformer eliminates y capacitor superior performance over linear and rcc ? hysteretic thermal shutdown protection ? automatic recovery improves � eld reliability ? universal input range allows worldwide operation ? auto-restart reduces delivered power by >85% during short circuit and open loop fault conditions ? simple on/off control, no loop compensation needed ? high bandwidth provides fast turn on with no overshoot and excellent transient load response ecosmart ? ? energy ef � ciency technology ? easily meets all global energy ef � ciency regulations with no added components ? no-load consumption <150 mw at 265 vac input ? on/off control provides constant ef � ciency to very light loads ? ideal for mandatory cec regulations applications ? chargers for cell/cordless phones, pdas, power tools, mp3/portable audio devices, shavers etc. ? standby and auxiliary supplies description linkswitch-lp switcher ics cost effectively replace all unregulated isolated linear transformer based (50/60 hz) power supplies up to 3 w output power. for worldwide operation, a single universal input design replaces multiple linear transformer based designs. the self-biased circuit achieves an extremely low no-load consumption of under 150 mw. the internal oscillator ? table 1. notes: 1. output power may be limited by speci � c application parameters including core size and clampless operation (see key application considerations). 2. minimum continuous power in a typical non-ventilated enclosed adapter measured at 50 c ambient. 3. minimum practical continuous power in an open frame design with adequate heat sinking, measured at 50 c ambient. 4. packages: p: dip-8b, g: smd-8b. for lead-free package options, see part ordering information. frequency is jittered to signi � cantly reduce both quasi-peak and average emi, minimizing � lter cost. october 2005 output power table 1 product 4 230 vac 15% 85-265 vac adapter 2 open frame 3 adapter 2 open frame 3 lnk562p or g 1.9 w 1.9 w 1.9 w 1.9 w lnk563p or g 2.5 w 2.5 w 2.5 w 2.5 w lnk564p or g 3 w 3 w 3 w 3 w (a) (b) + d s fb bp dc output ac in linkswitch-lp pi-3923-092705
2 lnk562-564 f 10/05 figure 2. functional block diagram. pin functional description drain (d) pin: the power mosfet drain connection provides internal operating current for both start-up and steady-state operation. bypass (bp) pin: a 0.1 f external bypass capacitor for the internally generated 5.8 v supply is connected to this pin. feedback (fb) pin: during normal operation, switching of the power mosfet is controlled by this pin. mosfet switching is disabled when a current greater than 70 a � ows into this pin. source (s) pin: this pin is the power mosfet source connection. it is also the ground reference for the bypass and feedback pins. linkswitch-lp functional description linkswitch-lp comprises a 700 v power mosfet switch with a power supply controller on the same die. unlike conventional pwm (pulse width modulation) controllers, it uses a simple on/off control to regulate the output voltage. the controller consists of an oscillator, feedback (sense and logic) circuit, 5.8 v regulator, bypass pin under-voltage circuit, over-temperature pi-3491-111903 fb d s bp s s s p package (dip-8b) g package (smd-8b) 8 5 7 1 4 2 3 figure 3. pin con � guration. protection, frequency jittering, current limit circuit, and leading edge blanking. oscillator the typical oscillator frequency is internally set to an average of 66/83/100 khz for the lnk562, 563 & 564 respectively. two signals are generated from the oscillator: the maximum duty cycle signal (dc max ) and the clock signal that indicates the beginning of each switching cycle. pi-3958-092905 clock jitter auto-re s tart counter fault pre s ent o s cillator 5.8 v 4.85 v s ourc e ( s ) s r q dc max adj bypa ss (bp) + - v i limit leading edge blanking thermal s hutdown + - drain (d) bypa ss pin under-voltage current limit comparator feedback (fb) open loop pulldown q 6.3 v 1.69 v -v th 0.8 v + regulator 5.8 v re s et 3 lnk562-564 f 10/05 the oscillator incorporates circuitry that introduces a small amount of frequency jitter, typically 5% of the switching frequency, to minimize emi. the modulation rate of the frequency jitter is set to 1 khz to optimize emi reduction for both average and quasi-peak emissions. the frequency jitter, which is proportional to the oscillator frequency, should be measured with the oscilloscope triggered at the falling edge of the drain voltage waveform. the waveform in figure 4 illustrates the frequency jitter. the oscillator frequency is reduced when the fb pin voltage is less than 1.69 v as described below. feedback input circuit the feedback input circuit at the fb pin consists of a low impedance source follower output set at 1.69 v. when the current delivered into this pin exceeds 70 a, a low logic level (disable) is generated at the output of the feedback circuit. this output is sampled at the beginning of each cycle on the rising edge of the clock signal. if high, the power mosfet is turned on for that cycle (enabled), otherwise the power mosfet remains off (disabled). since the sampling is done only at the beginning of each cycle, subsequent changes in the fb pin voltage or current during the remainder of the cycle are ignored. when the fb pin voltage falls below 1.69 v, the oscillator frequency linearly reduces to typically 48% at the auto-restart threshold voltage of 0.8 v. this function limits the power supply output current at output voltages below the rated voltage regulation threshold v r (see figure 1). 5.8 v regulator and 6.3 v shunt voltage clamp the 5.8 v regulator charges the bypass capacitor connected to the bypass pin to 5.8 v by drawing a current from the voltage on the drain, whenever the mosfet is off. the bypass pin is the internal supply voltage node. when the mosfet is on, the device runs off of the energy stored in the bypass capacitor. extremely low power consumption of the internal circuitry allows linkswitch-lp to operate continuously from the current drawn from the drain pin. a bypass capacitor value of 0.1 f is suf � cient for both high frequency decoupling and energy storage. in addition, there is a 6.3 v shunt regulator clamping the bypass pin at 6.3 v when current is provided to the bypass pin externally. this facilitates powering the device externally through a resistor from the bias winding to decrease the no- load consumption. bypass pin under-voltage the bypass pin under-voltage circuitry disables the power mosfet when the bypass pin voltage drops below 4.85 v. once the bypass pin voltage drops below 4.85 v, it must rise back to 5.8 v to enable (turn-on) the power mosfet. over-temperature protection the thermal shutdown circuitry senses the die temperature. the threshold is set at 142 c typical with a 75 c hysteresis. when the die temperature rises above this threshold (142 c) the power mosfet is disabled and remains disabled until the die temperature falls by 75 c, at which point the mosfet is re-enabled. current limit the current limit circuit senses the current in the power mosfet. when this current exceeds the internal threshold (i limit ), the power mosfet is turned off for the remainder of that cycle. the leading edge blanking circuit inhibits the current limit comparator for a short time (t leb ) after the power mosfet is turned on. this leading edge blanking time has been set so that current spikes caused by capacitance and recti � er reverse recovery time will not cause premature termination of the mosfet conduction. auto restart in the event of a fault condition such as output short circuit or an open loop condition, linkswitch-lp enters into auto-restart operation. an internal counter clocked by the oscillator gets reset every time the fb pin voltage exceeds the feedback pin auto-restart threshold voltage (v fb(ar) ). if the fb pin voltage drops below v fb(ar) for more than 100 ms, the power mosfet switching is disabled. the auto-restart alternately enables and disables the switching of the power mosfet at a duty cycle of typically 12% until the fault condition is removed. figure 4. frequency jitter at f osc . 600 020 68 khz 64 khz v drain time ( s) pi- 3 660-0 8 1 3 0 3 500 400 300 200 100 0 4 lnk562-564 f 10/05 applications example the circuit shown in figure 5 is a typical implementation of a 6 v, 330 ma, constant voltage, constant current (cv/cc) output power supply. ac input differential � ltering is accomplished with the very low cost input � lter stage formed by c1 and l1. the proprietary frequency jitter feature of the lnk564 eliminates the need for an input pi � lter, so only a single bulk capacitor is required. adding a sleeve may allow the input inductor l1 to be used as a fuse as well as a � lter component. this very simple filterfuse? input stage further reduces system cost. alternatively, a fusible resistor rf1 may be used to provide the fusing function. input diode d2 may be removed from the neutral phase in applications where decreased emi margins and/or decreased input surge withstand is allowed. in such applications, d1 will need to be an 800 v diode. the power supply utilizes simpli � ed bias winding voltage feedback, enabled by lnk564 on/off control. the resistor divider formed by r1 and r2 determine the output voltage across the transformer bias winding during the switch off time. in the v/i constant voltage region, the lnk564 device enables/disables switching cycles to maintain 1.69 v on the fb pin. diode d3 and low cost ceramic capacitor c3 provide recti � cation and � ltering of the primary feedback winding waveform. at increased loads, beyond the constant power threshold, the fb pin voltage begins to reduce as the power supply output voltage falls. the internal oscillator frequency is linearly reduced in this region until it reaches typically 50% of the starting frequency. when the fb pin voltage drops below the auto-restart threshold (typically 0.8 v on the fb pin, which is equivalent to 1 v to 1.5 v at the output of the power supply), the power supply will turn off for 800 ms and then turn back on for 100 ms. it will continue in this mode until the auto-restart threshold is exceeded. this function reduces the average output current during an output short circuit condition. no-load consumption can be further reduced by increasing c3 to 0.47 f or higher. a clampless primary circuit is achieved due to the very tight tolerance current limit trimming techniques used in manufacturing the lnk564, plus the transformer construction techniques used. peak drain voltage is therefore limited to typically less than 550 v at 265 vac, providing signi � cant margin to the 700 v minimum drain voltage speci � cation (bv dss ). output recti � cation and � ltering is achieved with output recti � er d4 and � lter capacitor c5. due to the auto-restart feature, the average short circuit output current is signi � cantly less than 1 a, allowing low cost recti � er d4 to be used. output circuitry is designed to handle a continuous short circuit on the power supply output. diode d4 is an ultra-fast type, selected for optimum v/i output characteristics. optional resistor r3 provides a pre- load, limiting the output voltage level under no-load output conditions. despite this pre-load, no-load consumption is within targets at approximately 140 mw at 265 vac. the additional margin of no-load consumption requirement can be achieved by increasing the value of r4 to 2.2 k ? or higher while still maintaining output voltage well below the 9 v maximum speci � cation. placement is left on the board for an optional zener clamp (vr1) to limit maximum output voltage under open loop conditions, if required. figure 5. 6 v, 330 ma cv/cc linear replacement power supply. d s fb bp j 3 -1 rtn 6 v, 0. 33 a j 3 -2 l j-1 j-2 n d1 1n4937 rf1* 8.2 ? 2.5 w c1 10 f 400 v c2 0.1 f 50 v l1 3300 h d4 uf4002 d3 1n4005 c5 220 f 25 v c3 330 nf 50 v c4* 100 pf 250 vac *optional components r3 2 k ? vr1* 1n5240b 10 v r2 3 k ? r1 37.4 k ? t1 ee16 2 1 7 6 4 5 d2 1n4005 90-265 vac linkswitch-lp pi-4106-101105 u1 lnk564p 5 lnk562-564 f 10/05 key application considerations output power table the data sheet maximum output power table (table 1) represents the maximum practical continuous output power level that can be obtained under the following assumed conditions: 1. the minimum dc input voltage is 90 v or higher for 85 vac input, or 240 v or higher for 230 vac input or 115 vac with a voltage doubler. the value of the input capacitance should be large enough to meet these criteria for ac input designs. 2. secondary output of 6 v with a schottky recti � er diode. 3. assumed ef � ciency of 70%. 4. voltage only output (no secondary-side constant current circuit). 5. discontinuous mode operation (k p > 1). 6. a suitably sized core to allow a practical transformer design (see table 2). 7. the part is board mounted with source pins soldered to a suf � cient area of copper to keep the source pin temperature at or below 100 c. 8. ambient temperature of 50 c for open frame designs and an internal enclosure temperature of 60 c for adapter designs. below a value of 1, k p is the ratio of ripple to peak primary current. above a value of 1, k p is the ratio of primary mosfet off time to the secondary diode conduction time. due to the � ux density requirements described below, typically a linkswitch-lp design will be discontinuous, which also has the bene � t of allowing lower-cost fast (vs. ultra-fast) output diodes and reducing emi. clampless designs clampless designs rely solely on the drain node capacitance to limit the leakage inductance induced peak drain-to-source voltage. therefore the maximum ac input line voltage, the value of v or , the leakage inductance energy, (a function of leakage inductance and peak primary current), and the primary winding capacitance determine the peak drain voltage. with no signi � cant dissipative element present, as is the case with an external clamp, the longer duration of the leakage inductance ringing can increase emi. the following requirements are recommended for a universal input or 230 vac only clampless design: 1. clampless designs should only be used for p o 2.5 w using a v or of 90 v 2. for designs with p o 2 w, a two-layer primary must be used to ensure adequate primary intra-winding capacitance in the range of 25 pf to 50 pf. 3. for designs with 2 < p o 2.5 w, a bias winding must be added to the transformer using a standard recovery recti � er diode (1n4003? 1n4007) to act as a clamp. this bias winding may also be used to externally power the device by connecting a resistor from the bias winding capacitor to the bypass pin. this inhibits the internal high voltage current source, reducing device dissipation and no-load consumption. 4. for designs with p o > 2.5 w, clampless designs are not practical and an external rcd or zener clamp should be used. 5. ensure that worst-case, high line, peak drain voltage is below the bv dss speci � cation of the internal mosfet and ideally 650 v to allow margin for design variation. v or (re � ected output voltage), is the secondary output plus output diode forward voltage drop that is re � ected to the primary via the turns ratio of the transformer during the diode conduction time. the v or adds to the dc bus voltage and the leakage spike to determine the peak drain voltage. audible noise the cycle skipping mode of operation used in linkswitch-lp can generate audio frequency components in the transformer. to limit this audible noise generation, the transformer should be designed such that the peak core � ux density is below 1500 gauss (150 mt). following this guideline and using the standard transformer production technique of dip varnishing, practically eliminates audible noise. vacuum impregnation of the transformer is not recommended, as it does not provide any better reduction of audible noise than dip varnishing. and although vacuum impregnation has the bene � t of increased transformer capacitance (which helps in clampless designs), it can also upset the mechanical design of the transformer, especially if shield windings are used. higher � ux densities are possible, increasing the power capability of the transformers above what is shown in table 2. however careful evaluation of the audible noise performance should be made using production transformer samples before approving the design. ceramic capacitors that use dielectrics such as z5u, when used in clamp circuits, may also generate audio noise. if this is the case, try replacing them with a capacitor having a different dielectric or construction, for example a � lm type. bias winding feedback to give the best output regulation in bias winding designs, a slow diode such as the 1n400x series should be used as the linkswitch-lp device core size lnk562 lnk563 lnk564 ee13 1.1 w 1.4 w 1.7 w ee16 1.3 w 1.7 w 2 w ee19 1.9 w 2.5 w 3 w table 2. estimate of transformer power capability vs. linkswitch-lp device and core size at a flux density of 1500 gauss (150 mt). 6 lnk562-564 f 10/05 recti � er. this effectively � lters the leakage inductance spike and reduces the error that this would give when using fast recovery time diodes. the use of a slow diode is a requirement in clampless designs. linkswitch-lp layout considerations layout see figure 6 for a recommended circuit board layout for linkswitch-lp . single point grounding use a single point ground connection from the input � lter capacitor to the area of copper connected to the source pins. bypass capacitor (c bp ) the bypass pin capacitor should be located as near as possible to the bypass and source pins. primary loop area the area of the primary loop that connects the input � lter capacitor, transformer primary and linkswitch-lp together should be kept as small as possible. primary clamp circuit an external clamp may be used to limit peak voltage on the drain pin at turn off. this can be achieved by using an rcd clamp or a zener (~200 v) and diode clamp across the primary winding. in all cases, to minimize emi, care should be taken to minimize the circuit path from the clamp components to the transformer and linkswitch-lp . thermal considerations the copper area underneath the linkswitch-lp acts not only as a single point ground, but also as a heatsink. as it is connected to the quiet source node, this area should be maximized for good heat sinking of linkswitch-lp . the same applies to the cathode of the output diode. + hv dc input - + input filter capacitor c bp - dc out output filter capacitor pi-4157-101305 maximize hatched copper areas ( ) for optimum heatsinking top view transformer linkswitch-lp d s s fb bp s s y1- capacitor figure 6. recommended circuit board layout for linkswitch-lp (assumes a hvdc input stage). 7 lnk562-564 f 10/05 y capacitor the placement of the y capacitor should be directly from the primary input � lter capacitor positive terminal to the common/ return terminal of the transformer secondary. such a placement will route high magnitude common-mode surge currents away from the linkswitch-lp device. note: if an input pi (c, l, c) emi � lter is used, then the inductor in the � lter should be placed between the negative terminals on the input � lter capacitors. output diode for best performance, the area of the loop connecting the secondary winding, the output diode and the output � lter capacitor should be minimized. in addition, suf � cient copper area should be provided at the anode and cathode terminals of the diode for heat sinking. a larger area is preferred at the quiet cathode terminal. a large anode area can increase high- frequency radiated emi. quick design checklist as with any power supply design, all linkswitch-lp designs should be veri � ed on the bench to make sure that component speci � cations are not exceeded under worst-case conditions. the following minimum set of tests is strongly recommended: 1. maximum drain voltage ? verify that v ds does not exceed 650 v at the highest input voltage and peak (overload) output power. a 50 v margin to the 700 v bv dss speci � cation gives margin for design variation, especially in clampless designs. 2. maximum drain current ? at maximum ambient temperature, maximum input voltage and peak output (overload) power, verify drain current waveforms for any signs of transformer saturation and excessive leading-edge current spikes at startup. repeat under steady state conditions and verify that the leading-edge current spike event is below i limit(min) at the end of the t leb(min) . under all conditions, the maximum drain current should be below the speci � ed absolute maximum ratings. 3. thermal check ? at specified maximum output power, minimum input voltage and maximum ambient temperature, verify that the temperature speci � cations are not exceeded for linkswitch-lp , transformer, output diode and output capacitors. enough thermal margin should be allowed for part-to-part variation of the r ds(on) of linkswitch-lp as speci � ed in the data sheet. under low line and maximum power, a maximum linkswitch-lp source pin temperature of 100 c is recommended to allow for these variations. design tools up-to-date information on design tools can be found at the power integrations web site: www.powerint.com. 8 lnk562-564 f 10/05 absolute maximum ratings (1,6) drain voltage .................................................. 700 v peak drain current...................................200 ma (375 ma) (2) peak negative pulsed drain current (see fig. 10) ... 100 ma (3) feedback voltage .........................................-0.3 v to 9 v feedback current.............................................100 ma bypass voltage ..........................................-0.3 v to 9 v storage temperature .......................................... -65 c to 150 c operating junction temperature (4) ..................... -40 c to 150 c lead temperature (5) ........................................................260 c notes: 1. all voltages referenced to source, t a = 25 c. 2. the higher peak drain current is allowed while the drain voltage is simultaneously less than 400 v. 3. duration not to exceed 2 s. 4. normally limited by internal circuitry. 5. 1/16 in. from case for 5 seconds. 6. maximum ratings speci � ed may be applied, one at a time, without causing permanent damage to the product. exposure to absolute maximum rating conditions for extended periods of time may affect product reliability. thermal impedance thermal impedance: p or g package: ( ja ) ........................... 70 c/w (2) ; 60 c/w (3) ( jc ) (1) ............................................... 11 c/w notes: 1. measured on pin 2 (source) close to plastic interface. 2. soldered to 0.36 sq. in. (232 mm 2 ), 2 oz. (610 g/m 2 ) copper clad. 3. soldered to 1 sq. in. (645 mm 2 ), 2 oz. (610 g/m 2 ) copper clad. parameter symbol conditions source = 0 v; t j = -40 to 125 c see figure 7 (unless otherwise speci � ed) min typ max units control functions output frequency f osc t j = 25 c v fb =1.69 v average lnk562 61 66 71 khz lnk563 77 83 89 lnk564 93 100 107 ratio of output frequency at auto- restart to f osc f osc(ar) t j = 25 c, v fb = v fb(ar) 48 % frequency jitter peak-peak jitter, t j = 25 c 5 % maximum duty cycle dc max s2 open 66 70 % feedback pin turnoff threshold current i fb t j = 25 c see note a 56 70 84 a feedback pin voltage at turnoff threshold v fb t j = 0 to 125 c see note a 1.60 1.69 1.78 v drain supply current i s1 v fb 2 v (mosfet not switching) see note b 160 220 a i s2 feedback open (mosfet switching) see notes b, c 220 260 a 9 lnk562-564 f 10/05 parameter symbol conditions source = 0 v; t j = -40 to 125 c see figure 7 (unless otherwise speci � ed) min typ max units control functions (cont.) bypass pin charge current i ch1 v bp = 0 v, t j = 25 c, see note d -5.5 -3.3 -1.8 ma i ch2 v bp = 4 v, t j = 25 c, see note d -3.8 -2.3 -1.0 bypass pin voltage v bp 5.55 5.8 6.10 v bypass pin voltage hysteresis v bph 0.8 0.95 1.2 v bypass pin supply current i bpsc see note e 84 a circuit protection current limit i limit di/dt = 40 ma/ s t j = 25 c 124 136 148 ma power coef � cient i 2 f di/dt = 40 ma/ s t j = 25 c lnk562 1099 1221 1380 a 2 hz lnk563 1381 1535 1735 lnk564 1665 1850 2091 leading edge blanking time t leb t j = 25 c see note f 220 265 ns thermal shutdown temperature t sd 135 142 150 c thermal shutdown hysteresis t shd see note g 75 c output on-state resistance r ds(on) i d = 13 ma t j = 25 c4855 ? t j = 100 c7688 off-state drain leakage current i dss v bp = 6.2 v, v fb 2 v, v ds = 560 v, t j = 25 c 50 a breakdown voltage bv dss v bp = 6.2 v, v fb 2 v, see note h, t j = 25 c 700 v drain supply voltage 50 v output enable delay t en see figure 9 17 s output disable setup time t dst 0.5 s 10 lnk562-564 f 10/05 parameter symbol conditions source = 0 v; t j = -40 to 125 c see figure 7 (unless otherwise speci � ed) min typ max units output (cont.) feedback pin auto-restart threshold voltage v fb(ar) t j = 25 c 0.8 v auto-restart on-time v fb = v fb(ar) t j = 25 c 100 ms auto-restart duty cycle dc ar 12 % notes: a. in a scheme using a resistor divider network at the fb pin, where r u is the resistor from the fb pin to the recti � ed bias voltage and r l is the resistor from the fb pin to the source pin, the output voltage variation is in � uenced by v fb and i fb variations. to determine the contribution from the v fb variation in percent, the following equation can be used: to determine the contribution from i fb variation in percent, the following equation can be used: since i fb and v fb are independent parameters, the composite variation in percent would be . b. total current consumption is the sum of i s1 and i dss when feedback pin voltage is 2 v (mosfet not switching) and the sum of i s2 and i dss when feedback pin is shorted to source (mosfet switching). c since the output mosfet is switching, it is dif � cult to isolate the switching current from the supply current at the drain. an alternative is to measure the bypass pin current at 6 v. d. see typical performance characteristics section figure 15 for bypass pin start-up charging waveform. e. this current is only intended to supply an optional optocoupler connected between the bypass and feedback pins and not any other external circuitry. f. this parameter is guaranteed by design. g. this parameter is derived from characterization. h. breakdown voltage may be checked against minimum bv dss by ramping the drain pin voltage up to but not exceeding minimum bv dss . v r rr ir v r rr ir x 100 1 () () () () fb typ l ul fb typ u fb max l ul fb typ u # = + + + + - j l k k k k b b n p o o o o l l v r rr ir v r rr ir y 100 1 () () () ( ) fb typ l ul fb typ u fb typ l ul fb max u # = + + + + - j l k k k k b b n p o o o o l l xy 22 ! + 11 lnk562-564 f 10/05 figure 7. general test circuit. pi-3490-060204 50 v 50 v d fb s s s s bp s1 470 k ? s2 0.1 f 470 ? 5 w pi-3707-112503 fb t p t en dc max t p = 1 f osc v drain (internal signal) figure 8. duty cycle measurement. figure 9. output enable timing. 0 100 time ( s ) drain current (ma) pi-4021-101305 -100 2 s figure 10. peak negative pulsed drain current waveform. 12 lnk562-564 f 10/05 1.4 1.0 1.2 0.8 0.6 0.4 0.2 0 -50 0 50 100 150 temperature ( c) pi-4164-100505 current limit (normalized to 25 c) 100 150 175 200 125 0 0 4 28 6 101214161820 drain voltage (v) drain current (ma) pi-3927-083104 25 75 50 25 c 100 c typical performance characteristics figure 15. bypass pin start-up waveform. 1.1 1.0 0.9 -50 -25 0 25 50 75 100 125 150 junction temperature ( c) breakdown volta g e (normalized to 25 c) pi-221 3 -012 3 01 6 5 4 3 2 1 0 0 0.2 0.4 0.6 0.8 1.0 time (ms) pi-2240-012 3 01 bypass pin volta g e (v) 7 figure 11. breakdown vs. temperature. figure 13. current limit vs. temperature. figure 16. output characteristics. 1.2 1.0 0.8 0.6 0.4 0.2 0 -50 -25 0 25 50 75 100 125 junction temperature ( c) pi-26 8 0-012 3 01 output frequency (normalized to 25 c) figure 12. frequency vs. temperature. 1.1 1.0 0.9 -50 -25 0 25 50 75 100 125 150 temperature ( c) feedback pin volta g e (normalized to 25 c) pi-4057-071905 figure 14. feedback pin voltage vs. temperature. 13 lnk562-564 f 10/05 figure 17. c oss vs. drain voltage. drain volta g e (v) drain capacitance (pf) pi- 3 92 8 -0 83 104 0 100 200 300 400 500 600 1 10 100 1000 typical performance characteristics (cont.) part ordering information linkswitch product family lp series number package identi � er g plastic surface mount dip p plastic dip lead finish n pure matte tin (pb-free) tape & reel and other options blank standard con � gurations tl tape & reel, 1000 pcs minimum, g package only lnk 562 g n - tl 14 lnk562-564 f 10/05 notes: 1. packa g e dimensions conform to jedec specification ms-001-ab (issue b 7/ 8 5) for standard dual-in-line (dip) packa g e with . 3 00 inch row spacin g . 2. controllin g dimensions are inches. millimeter sizes are shown in parentheses. 3 . dimensions shown do not include mold flash or other protrusions. mold flash or protrusions shall not exceed .006 (.15) on any side. 4. pin locations start with pin 1, and continue counter-clock- wise to pin 8 when viewed from the top. the notch and/or dimple are aids in locatin g pin 1. pin 6 is omitted. 5. minimum metal to metal spacin g at the packa g e body for the omitted lead location is .1 3 7 inch ( 3 .4 8 mm). 6. lead width measured at packa g e body. 7. lead spacin g measured with the leads constrained to be perpendicular to plane t. .00 8 (.20) .015 (. 38 ) . 3 00 (7.62) bsc (note 7) . 3 00 (7.62) . 3 90 (9.91) . 3 67 (9. 3 2) . 38 7 (9. 83 ) .240 (6.10) .260 (6.60) .125 ( 3 .1 8 ) .145 ( 3 .6 8 ) .057 (1.45) .06 8 (1.7 3 ) .120 ( 3 .05) .140 ( 3 .56) .015 (. 38 ) minimum .04 8 (1.22) .05 3 (1. 3 5) .100 (2.54) bsc .014 (. 3 6) .022 (.56) -e- pin 1 seating plane -d- -t- p0 8 b dip- 8 b pi-2551-121504 d s .004 (.10) t e d s .010 (.25) m (note 6) .1 3 7 ( 3 .4 8 ) minimum smd- 8 b pi-2546-121504 .004 (.10) .012 (. 3 0) .0 3 6 (0.91) .044 (1.12) .004 (.10) 0 - 8 . 3 67 (9. 3 2) . 38 7 (9. 83 ) .04 8 (1.22) .009 (.2 3 ) .05 3 (1. 3 5) .0 3 2 (. 8 1) .0 3 7 (.94) .125 ( 3 .1 8 ) .145 ( 3 .6 8 ) -d- notes: 1. controllin g dimensions are inches. millimeter sizes are shown in parentheses. 2. dimensions shown do not include mold flash or other protrusions. mold flash or protrusions shall not exceed .006 (.15) on any side. 3 . pin locations start with pin 1, and continue counter-clock- wise to pin 8 when viewed from the top. pin 6 is omitted. 4. minimum metal to metal spacin g at the packa g e body for the omitted lead location is .1 3 7 inch ( 3 .4 8 mm). 5. lead width measured at packa g e body. 6. d and e are referenced datums on the packa g e body. .057 (1.45) .06 8 (1.7 3 ) (note 5) e s .100 (2.54) (bsc) . 3 72 (9.45) .240 (6.10) . 388 (9. 8 6) .1 3 7 ( 3 .4 8 ) minimum .260 (6.60) .010 (.25) -e- pin 1 d s .004 (.10) g0 8 b .420 .046 .060 .060 .046 .0 8 0 pin 1 .0 8 6 .1 8 6 .2 8 6 solder pad dimensions 15 lnk562-564 f 10/05 16 lnk562-564 f 10/05 revision notes date e 1) final release data sheet 10/05 f 2) revision of pi-3924 10/05 for the latest updates, visit our website: www.powerint.com power integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. power integrations does not assume any liability arising from the use of any device or circuit described herein. power integrations makes no warranty herein and s pecifically disclaims all warranties including, without limitation, the implied warranties of merchantability, fitness for a particular purpose, and non-infringement of third party rights. patent information the products and applications illustrated herein (including transformer construction and circuits external to the products) may be covered by one or more u.s. and foreign patents, or potentially by pending u.s. and foreign patent applications assigned to power integrations. a complete list of power integrations patents may be found at www.powerint.com. power integrations grants its customers a license under certain patent rights as set forth at http://www.powerint.com/ip.htm. life support policy power integrations products are not authorized for use as critical components in life support devices or systems without the express written approval of the president of power integrations. as used herein: 1. a life support device or system is one which, (i) is intended for surgical implant into the body, or (ii) supports or susta ins life, and (iii) whose failure to perform, when properly used in accordance with instructions for use, can be reasonably expected to result in signi � cant injury or death to the user. 2. a critical component is any component of a life support device or system whose failure to perform can be reasonably expecte d to cause the failure of the life support device or system, or to affect its safety or effectiveness. the pi logo, topswitch , tinyswitch , linkswitch , dpa-switch , ecosmart , clampless , e-shield , filterfuse , pi expert and pi facts are trademarks of power integrations, inc. other trademarks are property of their respective companies. ?copyright 2005, power integrations, inc. power integrations worldwide sales support locations world headquarters 5245 hellyer avenue san jose, ca 95138, usa. main: +1-408-414-9200 customer service: phone: +1-408-414-9665 fax: +1-408-414-9765 e-mail: usasales@powerint.com china (shanghai) rm 807-808a pacheer commercial centre, 555 nanjing rd. west shanghai, p.r.c. 200041 phone: +86-21-6215-5548 fax: +86-21-6215-2468 e-mail : chinasales@powerint.com china (shenzhen) rm 2206-2207, block a, electronics science & technology bldg. 2070 shennan zhong rd. shenzhen, guangdong, china, 518031 phone: +86-755-8379-3243 fax: +86-755-8379-5828 e-mail: chinasales@powerint.com germany rueckertstrasse 3 d-80336, munich germany phone: +49-89-5527-3910 fax: +49-89-5527-3920 e-mail: eurosales@powerint.com india 261/a, ground floor 7th main, 17th cross, sadashivanagar bangalore, india 560080 phone: +91-80-5113-8020 fax: +91-80-5113-8023 e-mail: indiasales@powerint.com italy via vittorio veneto 12 20091 bresso mi italy phone: +39-028-928-6000 fax: + 39-028-928-6009 e-mail: eurosales@powerint.com japan keihin tatemono 1st bldg 2-12-20 shin-yokohama, kohoku-ku, yokohama-shi, kanagawa ken, japan 222-0033 phone: +81-45-471-1021 fax: +81-45-471-3717 e-mail: japansales@powerint.com korea rm 602, 6fl korea city air terminal b/d, 159-6 samsung-dong, kangnam-gu, seoul, 135-728, korea phone: +82-2-2016-6610 fax: +82-2-2016-6630 e-mail: koreasales@powerint.com singapore 51 newton road #15-08/10 goldhill plaza singapore, 308900 phone: +65-6358-2160 fax: +65-6358-2015 e-mail: singaporesales@powerint.com taiwan 5f, no. 318, nei hu rd., sec. 1 nei hu dist. taipei, taiwan 114, r.o.c. phone: +886-2-2659-4570 fax: +886-2-2659-4550 e-mail: taiwansales@powerint.com europe hq 1st floor, st. james s house east street, farnham surrey gu9 7tj united kingdom phone: +44 (0) 1252-730-140 fax: +44 (0) 1252-727-689 e-mail: eurosales@powerint.com applications hotline world wide +1-408-414-9660 applications fax world wide +1-408-414-9760 |
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