? semiconductor components industries, llc, 2005 february, 2005 ? rev. 2 1 publication order number: ncp1835/d ncp1835 integrated li?ion charger ncp1835 is an integrated linear charger specifically designed to charge 1 ? cell li ? ion batteries with a constant current, constant voltage (cccv) profile. it can charge at currents of up to 1.0 a. its low input voltage capability, adjustable charge current, ability to maintain regulation without a battery, and its onboard thermal foldback make it versatile enough to charge from a variety of wall adapters. the ncp1835 can charge from a standard voltage ? source wall adapter as a cccv charger, or from a current limited adapter to limit power dissipation in the pass device. features ? integrated voltage and current regulation ? no external mosfet, sense resistor or blocking diode required ? charge current thermal foldback ? integrated pre ? charge current for conditioning deeply discharged battery ? integrated end ? of ? charge (eoc) detection ? 1% voltage regulation ? 4.2 v or 4.242 v regulated output voltage ? regulation maintained without a battery present ? programmable full charge current 300 ? 1000 ma ? open ? drain charger status and fault alert flags ? 2.8 v output for ac present indication and powering charging subsystems ? minimum input voltage of 2.4 v allows use of current limited adapters ? automatically recharging if battery voltage drops after charging cycle is completed ? low profile 3x3 mm dfn package ? pb ? free package is available typical applications ? cellular phones ? pdas, mp3 players ? stand ? alone chargers ? battery operated devices http://onsemi.com 1835 = device code 4200 = 4.2 v 4242 = 4.242 v a = assembly location l = wafer lot y = year w = work week 1 1 1835 4200 alyw dfn 3x3 mn suffix case 485c marking diagrams pin connections (top view) v cc bat fault cflg gnd vsns isel en timer v2p8 1 2 3 4 5 10 9 8 7 6 dfn 3x3 device package shipping ? ordering information ncp1835mn20r2 dfn ? 10 3000 units/reel 1 1835 4242 alyw ncp1835mn20r2g dfn ? 10 (pb ? free) 3000 units/reel ?for information on tape and reel specifications, including part orientation and tape sizes, please refer to our tape and reel packaging specification brochure, brd801 1/d. ncp1835mn24r2 dfn ? 10 3000 units/reel NCP1835MN24R2G dfn ? 10 (pb ? free) 3000 units/reel ncp1835mn24t2 dfn ? 10 3000 units/reel ncp1835mn24t2g dfn ? 10 (pb ? free) 3000 units/reel
ncp1835 http://onsemi.com 2 fault v cc cflg v2p8 en vsns bat gnd isel timer ncp1835 v in 80 k r isel 4.7 � f c in gnd 15 nf c t microprocessor 4.7 � f c out figure 1. typical application circuit v in 0.1 � f c 2p8 pin function description pin symbol description 1 v cc input supply voltage. provides power to the charger. this pin should be bypassed with at least a 4.7 � f ceramic capacitor to ground. 2 fault an open ? drain output indicating fault status. this pin is pulled low under any fault conditions. a fault condition resets the counter. 3 cflg an open ? drain output indicating charging or end ? of ? charge states. the cflg pin is pulled low when the charger is charging a battery. it is forced open when the charge current drops to i eoc . this high impedance mode will be latched until a recharge cycle or a new charge cycle starts. 4 timer connecting a timing capacitor, c time between this pin and ground to set end ? of ? charge timeout timer. timeout = 14*c time /1.0 nf (minute). the total charge for cc and cv mode is limited to the length of timeout. t rickle charge has a time limit of 1/8 of the timeout period. 5 gnd ground pin of the ic. for thermal consideration, it is recommended to solder the exposed metal pad on the backside of the package to ground. 6 en enable logic input. connect the en pin to low to disable the charger or leave it floating to enable the charger. 7 v2p8 2.8 v reference voltage output. this pin outputs a 2.8 v voltage source when an adapter is present. the maximum loading for this pin is 2.0 ma. 8 isel the full charge current (i fchg ) can be set by connecting a resistor, r isel , from the isel pin to ground. i fchg = (0.8*10 5 / r isel ) a, the pre ? charge current i pc = (0.1*i fchg) a and the end ? of ? charge threshold current i eoc = (0.1*i fchg ) a. for best accuracy, a resistor with 1% tolerance is recommended. 9 vsns battery voltage sense pin. connect this as close as possible to the battery input connection. 10 bat charge current output. a minimum 4.7 � f capacitor is needed for stability when the battery is not attached.
ncp1835 http://onsemi.com 3 maximum ratings rating symbol value unit supply voltage v cc 7.0 v status flag output pins v fault , v cflg 7.0 v voltage range for other pins v io 5.5 v current out from bat pin i o 1.2 a thermal characteristics thermal resistance, junction ? to ? air (note 3) power dissipation, t a = 25 c (note 3) r � ja p d 68.5 1.09 c/w w moisture sensitivity (note 4) msl level 1 operating ambient t emperature t a ? 20 to 70 c storage t emperature t stg ? 55 to 125 c esd human body model machine model hbm mm 2000 200 v v maximum ratings are those values beyond which device damage can occur. maximum ratings applied to the device are individual stress limi t values (not normal operating conditions) and are not valid simultaneously. if these limits are exceeded, device functional operation is not implied, damage may occur and reliability may be af fected. 1. this device series contains esd protection and is tested per the following standards: human body model (hbm) per jedec standard: jesd22 ? a114. machine model (mm) per jedec standard: jesd22 ? a115. 2. latchup current maximum rating: 150 ma per jedec standard: jesd78. 3. measure on 1 inch sq. of 1 oz. copper area. r � ja is highly dependent on the pcb heatsink area. for example, r � ja can be 38 c/w on 1 inch sq. of 1 oz. copper area on 4 layer pcb that has 1 single signal layer with the additional 3 solid ground or power planes. the maximum package power dissipation limit must not be exceeded: p d � t j(max) � t a r � ja with r � ja = 68.5 c/w, t j(max) = 100 c, p d = 1.09 w. 4. moisture sensitivity level per ipc/jedec standard: j ? std ? 020a.
ncp1835 http://onsemi.com 4 electrical characteristics (typical values are tested at v cc = 5.0 v and room temperature, maximum and minimum values are guaranteed over 0 c to 70 c with a supply voltage in the range of 4.3 v to 6.5 v, unless otherwise noted.) characteristic symbol min typ max unit v cc supply operating supply range v cc 2.8 ? 6.5 v rising v cc threshold v rise 3.0 3.4 3.95 v falling v cc lockout threshold v fall 2.0 2.4 2.8 v quiescent v cc pin supply current shutdown (en = low) normal operation (en = high) i vcc i vcc ? ? 30 1.0 ? ? � a ma battery drain current manual shutdown (v cc = 5.0 v, vsns = 4.0 v, en = low) i bms ? ? 3.0 � a charging performance regulated output voltage in constant voltage (cv) mode 4.2 v version, i chg = 10 ma 4.242 v version, i chg = 10 ma v reg 4.158 4.200 4.200 4.242 4.242 4.284 v dropout voltage (v bat = 3.7 v, i chg = 0.5 a) ? ? 200 300 mv pre ? charge threshold v oltage v pc 2.52 2.8 3.08 v pre ? charge current (r isel = 80 k � , v bat = 2.0 v) i pc 78 100 122 ma recommended full charge current i fchg 300 ? 1000 ma full ? charge current in constant current (cc) mode (r isel = 80 k � , v bat = 3.7 v) i fchg 0.9 1.0 1.1 a end ? of ? charge threshold (r isel = 80 k � , v bat = v reg ) i eoc 78 100 122 ma recharge voltage threshold v rech 3.9 4.03 4.155 v thermal foldback limit (junction temperature) (note 5) t lim ? 100 ? c oscillator oscillation period (c time = 15 nf) t osc 2.4 3.0 3.6 ms status flags cflg pin recommended maximum operating v oltage v cflg ? ? 6.5 v fault pin recommended maximum operating v oltage v fault ? ? 6.5 v cflg pin sink current (v cflg = 0.8 v) i cflg 5.0 ? ? ma fault pin sink current (v fault = 0.8 v) i fault 5.0 ? ? ma 5. guaranteed by design. not tested in production.
ncp1835 http://onsemi.com 5 typical operating characteristics 4.5 5.0 5.5 6.0 6.5 v cc , input voltage (v) v 2p8 , v2p8 voltage (v) 3.00 2.95 2.90 2.85 2.80 2.75 2.70 0 0.2 0.4 0.6 0.8 1 i chg , charge current (a) v reg , regulated output voltage (v) 4.30 4.25 4.20 4.15 4.10 4.05 4.00 figure 2. regulated output voltage vs. charge current figure 3. regulated output voltage (floating) vs. input voltage figure 4. regulated output voltage vs. temperature figure 5. isel voltage vs. input voltage figure 6. v2p8 voltage vs. input voltage 4.242 v 4.2 v 4.5 5 5.5 6 6.5 v cc , input voltage (v) v reg , regulated output voltage (v) 4.30 4.25 4.20 4.15 4.10 4.05 4.00 4.242 v 4.2 v ? 50 ? 25 0 25 50 75 t a , ambient temperature ( c) v reg , regulated output voltage (v) 4.30 4.25 4.20 4.15 4.10 4.05 4.00 v cc = 5 v v bat floating 100 125 v cc = 5 v r isel = 80 k 4.242 v 4.2 v 4.5 5.0 5.5 6.0 6.5 v cc , input voltage (v) v isel , isel voltage (v) 0.78 0.76 0.74 0.72 0.70 0.80 4.242 v 4.2 v v bat = 3.7 v r isel = 80 k 4.242 v 4.2 v v bat floating r isel = 80 k i v2p8 = 0 r isel = 80 k
ncp1835 http://onsemi.com 6 typical operating characteristics 2.5 3.0 3.5 4.0 4.5 v bat , battery voltage (v) i chg , charge current (ma) 800 600 400 200 0 1000 figure 7. v2p8 voltage vs. input voltage figure 8. trickle charge current vs. input voltage figure 9. trickle charge current vs. t emperature figure 10. full charge current vs. input voltage 4.3 4.5 4.7 4.9 5.1 v cc , input voltage (v) v 2p8 , v2p8 voltage (v) 3.0 2.5 2.0 1.5 1.0 0.5 0.0 5.3 5.5 3.7 3.9 4.1 4.5 5.0 5.5 6.0 6.5 v cc , input voltage (v) i pc , trickle charge current (ma) 110 100 90 80 120 ? 50 ? 25 0 25 50 75 t a , ambient temperature ( c) i pc , trickle charge current (ma) 120 110 100 90 80 70 60 v cc = 5 v v bat = 2.0 v 100 125 4.5 5.0 5.5 6.0 6.5 v cc , input voltage (v) i fchg , full charge current (ma) 1100 1000 900 800 1200 4.242 v 4.2 v v cc = 5 v 4.5 5.0 5.5 6.0 6.5 v cc , input voltage (v) v rech , recharge voltage (v) 4.10 4.05 4.00 3.95 3.90 figure 11. recharge voltage vs. input voltage r isel = 80 k figure 12. charge current vs. battery voltage v bat = 3.7 v r isel = 80 k v bat = 2.0 v r isel = 80 k v bat = 3.7 v r isel = 80 k
ncp1835 http://onsemi.com 7 detailed operating description overview rechargeable li ? ion/polymer batteries are normally charged with a constant current (cc) until the terminal voltage reaches a fixed voltage threshold, at which point a constant voltage (cv) is applied and the current drawn by the battery decays. the charging rate is determined by the specific rating of the battery. for example, if the battery is rated at 800 ma ? hours, then the recommended maximum charge rate is 800 ma. for a severely discharged cell, it takes approximately 2.5 ? 3.5 hours to recharge the battery at the maximum rate. so, when one charges at less than the maximum charge rate, the recharge time increases. also, the battery should not be continuously charged or the battery could age faster than necessary. because of this, li ? ion charging systems need to stop charging within a prescribed time limit regardless of the charge rate. the ncp1835 is a fully integrated, stand ? alone 1 ? cell li ? ion charger which performs the primary battery charging functions and includes a timer which will terminate charging if the battery has not completed charging within a prescribed time period. the char ging rate is user programmable up to 1.0 a and the end ? of ? charge timer is also programmable. the ncp1835 has a thermal foldback loop which reduces the charge rate if the junction temperature is exceeded. the device also includes several outputs which can be used to drive led indicators or interface to a microprocessor to provide status information. the adapter providing power to the charger can be a standard fixed output voltage such as a 5.0 v wall adapter or it can be a simple current limited adapter. the ncp1835 comes in two versions with output voltage regulation thresholds of 4.2 or 4.242 v depending on the requirements of the specific battery pack being used. the user determines the charge current by selecting the resistor r isel and determines the length of the end ? of ? charge timeout timer by selecting the capacitor, c time . charging operation figure 13 outlines the charging algorithm of the ncp1835 and figure 14 graphically illustrates this. when the charger is powered up and the input voltage rises above the power ? on, rising threshold (nominally 3.4 v), the charger initiates the charging cycle. the ncp1835 first determines the cell voltage. if it is less than the pre ? charge threshold (2.8 v), the ic recognizes the battery as severely discharged. in this state, the ncp1835 pre ? conditions (trickle charges) the battery by charging it at 10% of the full charge rate (i pc ). this slow charge prevents the battery from being damaged from high fast charge currents when it is in a deeply discharged state. the battery voltage should be trickle charged up to 2.8 v before 1/8 of the preset end ? of ? charge time is expired. if it cannot reach this voltage, than the battery is possibly shorted or damaged. therefore, the ncp1835 stops charging and the pre ? charge timeout signal asserts the fault flag. once the cell voltage crosses the pre ? charge threshold, the device will transition to normal (full ? rate) charging at 100% of the programmed full rate charge current (i fchg ). as the ncp1835 charges the battery, the cell voltage rises until it reaches the v reg threshold, (4.2 or 4.242 v). at the maximum charge rate, it normally takes about 1 hour to reach this point from a fully discharged state, and the battery will be approximately 70 ? 80% recharged. at this point, the charge transitions to constant voltage mode where the ic forces the battery to remain at a constant voltage, v reg . during this constant voltage state, the current required to maintain v reg steadily decreases as the battery approaches full charge. charge current eventually falls to a very low value as the battery approaches a fully charged condition. the ncp1835 monitors the current into the battery until it drops to 10% of the full charge rate. this is the end ? of ? charge (eoc) threshold. normally it takes 1.5 ? 2.5 hours to reach this point. once the ncp1835 reaches end ? of ? charge it opens the cflg pin and enters the eoc state. the ic continues to charge the battery until it reaches timeout. at that point, the ncp1835 stops charging. if the system does not reach eoc during the timeout period, the ncp1835 views this as a system fault and asserts the fault flag. if the battery voltage drops below the recharge threshold (which can occur if the battery is loaded), the ic reinitializes the charging sequence and begins a new charge cycle. the recharge voltage threshold, v rech , is nominally 4.03 v. in the inhibit state, the ncp1835 continues to monitor the battery voltage, but does not charge the battery. again, if the battery voltage drops below the recharge threshold the ic reinitializes the charging sequence and begins a new charge cycle.
ncp1835 http://onsemi.com 8 power up v cc > v por ? n y por n y end ? of ? charge or fault n n n y y trickle charge constant current charge n n y constant voltage charge y y y n n y inhibit y n figure 13. charging flow chart n y charging flow chart initialization reset counter trickle charge v sns > v pc ? 1/8 timeout? cc charge v sns v reg ? timeout? cv charge i ch < i eoc ? timeout? set fault low latch up charger en toggled? eoc indication; set cflg high keep fault high v sns < v rech ? timeout? charger inhibited reset counter v sns < v rech ? start recharge
ncp1835 http://onsemi.com 9 figure 14. typical charging diagram trickle charge cc charge cv charge end of charge recharging v reg v pc v rech v reg v reg i chg i chg i pc i eoc v in v bat i charge 0 time time time cflg fault v2p8 2.8 v time time time inhibit v rise table 1. charge status condition cflg fault trickle, constant current and constant v oltage charge low high end ? of ? charge or shutdown mode high high timeout fault, v isel < 0.35 v or v isel > 1.4 v high low
ncp1835 http://onsemi.com 10 charge status indicator (cflg ) cflg is an open ? drain output that indicates battery charging or end ? of ? charge (eoc) status. it is pulled low when charging in constant current mode and constant voltage mode. it will be forced to a high impedance state when the charge current drops to i eoc . when the charger is in shutdown mode, cflg will also stay in the high impedance state. fault indicator (fault ) fault is an open ? drain output that indicates that a charge fault has occurred. it has two states: low or high impedance. in a normal charge cycle, it stays in a high impedance state. at fault conditions, it will be pulled low and terminate the charge cycle. a timeout fault occurs when the full charge or pre ? charge timeouts are violated, or if the voltage on isel is greater than 1.4 v or lower than 0.35 v. there are two ways to get the charger out of a fault condition and back to a normal char ge cycle. one can either toggle the en pin from gnd to a floating state or reset the input power supply. adapter present indicator (v2p8) v2p8 is an input power supply presence indicator. when the input voltage, v cc , is above the power on threshold (v rise , nominally 3.4 v) and is also 100 mv above the battery voltage, it provides a 2.8 v reference voltage that can source up to 2.0 ma. this voltage can also be used to power a microprocessor i/o. enable/disable (en) pulling the en pin to gnd disables the ncp1835. in shutdown mode, the internal reference, oscillator, and control circuits are all turned off. this reduces the battery drain current to less than 3.0 � a and the input supply current to 30 � a. floating the en pin enables the charger. thermal foldback an internal thermal foldback loop reduces the programmed charge current proportionally if the die temperature rises above the preset thermal limit (nominally 100 c). this feature provides the charger protection from over heating or thermal damage. figure 15 shows the full charge current reduction due to die temperature increase across the thermal foldback limit. for a charger with a 1.0 a constant charge current, the charge current starts decreasing when the die temperature hits 100 c and is reduced to zero when the die temperature rises to 110 c. figure 15. full charge current vs. junction temperature � ? 100 ma/c 100 c i fchg i chg , charge current t j , junction temperature
ncp1835 http://onsemi.com 11 application information input and output capacitor selection a 4.7 � f or higher value ceramic capacitor is recommended for the input bypass capacitor. for the output capacitor, when there is no battery inserted and the ncp1835 is used as an ldo with 4.2 v or 4.242 v output voltage, a 4.7 � f or higher value tantalum capacitor is recommended for stability. with the battery attached, the output capacitor can be any type with the value higher than 0.1 � f. r isel resistor selection for programming charge current a single resistor, r isel, between the isel pin and ground programs the pre ? charge current, full charge current, and end ? of ? charge detection threshold. the nominal voltage of isel is 0.8 v. the charge current out of bat pin is 100,000 times the current out of isel pin. therefore, the full charge current (i fchg ) is: i fchg � 100, 000 � 0.8 r isel (a) (eq. 1) i pc and i eoc are 10% of the value programmed above with the r isel resistor. the following table and curves show the selection of the resistance value for desired currents. table 2. charge current vs. r isel i fchg (ma) i pc / i eoc (ma) r isel (k � ) 300 30 267 500 50 160 600 60 133.3 700 70 114.3 800 80 100 900 90 88.9 1000 100 80 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 80 100 120 140 160 180 200 r isel (k � ) i fchg (a) figure 16. full ? charge current (i fchg ) vs. current select resistor (r isel ) 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 0.16 0.18 80 100 120 140 160 180 20 0 figure 17. pre ? charge current (i pchg ) vs. current select resistor (r isel ) r isel (k � ) i pchg (a) c time selection for programming charge time the ncp1835 offers an end ? of ? charge timeout timer to prevent the battery from continuously charging which can cause premature aging or safety issues. the timing capacitor between timer pin and ground, c time , sets the end ? of ? charge time, timeout, and the pre ? charge timeout. this capacitor is required for proper device operation. the internal oscillator charges c time to 1.2 v and then discharges it to 0.6 v with 6 � a current in one period. therefore, the period of the oscillator is: t osc � 2 � c time � dv c i c � 0.2 � 10 6 � c time (sec) (eq. 2) a 22 ? binary counter counts every oscillator period until it reaches the maximum number corresponding to end ? of ? charge time, timeout. timeout � 2 22 � t osc � 14 � c time 1nf (minute) (eq. 3) the ncp1835 will terminate charging and give a timeout signal if the battery has not completed charging within the timeout period. the timeout signal then forces the fault pin low.
ncp1835 http://onsemi.com 12 the following table 3 shows the desired timeout vs. c time sizes. the c time is required for proper device operation. table 3. timeout vs. c time size c time (nf) timeout (minute) 0.47 6.6 1 14 5.6 78 8.2 115 10 140 15 210 33 462 56 784 thermal considerations the ncp1835 is housed in a thermally enhanced 3x3 mm dfn package. in order to deliver the maximum power dissipation under all conditions, it is very important that the user solders exposed metal pad under the package to the ground copper area and then connect this area to a ground plane through thermal vias. this can greatly reduce the thermal impedance of the device and further enhance its power dissipation capability and thus its output current capability. charging with constant voltage adapters or current limited adapters the ncp1835 can be powered from two types of regulated adapters: a traditional constant voltage type or a current limited type. figure 18 illustrates the operation of the linear charger powered with a standard constant voltage adapter. the power dissipation in the linear charger is: p dis � (v cc � v bat) � i chg (eq. 4) the maximum power dissipation p1 happens at the beginning of a full current charge, since this is the point that the power supply and the battery voltage have the largest difference. as the battery voltage rises during char ging, the power dissipation drops. after entering the constant voltage mode, the power dissipation drops further due to the decreasing charge current. the maximum power that the linear charger can dissipate is dependent on the thermal resistance of the device. in case the device can not handle the maximum power p1, the thermal foldback loop reduces the charge current which limits the power dissipation to the sustained level p2. figure 18 shows this. using the adapter?s current limit can provide better thermal performance than the above example. a current limited adapter operates as a constant voltage adapter before the charge current reaches the current limit. i lim must be less than the programmed full charge current i fchg . once the current limit is reached, the adapter will source the current limit i lim while its output voltage will drop to follow the battery voltage. if the application uses the adapter to power its systems while the battery is being charged, this drooping voltage can be an issue. the worst case power dissipation with a current limited adapter occurs at the beginning of the constant voltage mode, which is shown at point p3 in figure 19. if p3 is higher than p2, the maximum power dissipation that the charger can handle, then the thermal foldback function will be activated. trickle charge cc charge cv charge inhibit v reg v pc i fchg i pc v in v bat i charge p dis 0 time time time time figure 18. typical charge curves with a constant voltage adapter p1 p2 trickle charge cc charge cv charge inhibit v in v bat i charge p dis 0 v reg v pc i fchg i lim i pc time time time time figure 19. typical charge curves with a current limited adapter p3
ncp1835 http://onsemi.com 13 pcb layout recommendations the recommended footprint for the 3x3 mm dfn package is included on the package dimension page. it is critical that the exposed metal pad is properly soldered to the ground copper area and then connected to a ground plane through thermal vias. the maximum recommended thermal via diameter is 12 mils (0.305 mm). limited by the size of the pad, six thermal vias should allow for proper thermal regulation without sacrificing too much copper area within the pad. the copper pad is the primary heatsink and should be connected to as much top layer metal as possible to minimize the thermal impedance. figure 20 illustrates graphically the recommended connection for the exposed pad with vias. gnd figure 20. recommended footprint the following is a ncp1835 demo board schematic, layout, and suggested bill of materials. figure 21. demo board schematic v cc (t8) c5 gnd (t9) fault (t5) r4 d1 cflg (t6) r5 d2 timer v2p8 vcc fault cflg gnd bat vsns isel en timer (t10) c4 vcc r3 2 1 jp2 c3 r8 d3 v2p8 (t4) r2 r9 2 1 jp1 r1 c1 c2 + ? gnd (t2) li ? ion battery vsns (t7) v bat (t1) ncp1835
ncp1835 http://onsemi.com 14 figure 22. silkscreen layer figure 23. top layer fi g ure 24. bottom la y er
ncp1835 http://onsemi.com 15 table 4. bill of materials item qty. part description designators suppliers part number 1 1 ncp1835 integrated li ? ion charger (dfn ? 10) u1 on semiconductor ncp1835 2 1 chip resistor � 1% 0 � (0603) r1 vishay crcw06030r00f 3 2 chip resistor � 1% 160 k � (0603) r2, r9 vishay crcw06031603f 4 1 chip resistor � 1% 100 k � (0603) r3 vishay crcw06031003f 5 2 chip resistor � 1% 1.0 k � (0603) r4, r5 vishay crcw06031001f 6 1 chip resistor � 1% 432 � (0603) r8 vishay crcw06034320f 8 1 chip capacitor 1.0 � f/16 v, � 20% (0805) c1 panasonic ecjgvb1c105m 9 1 chip capacitor 4.7 � f/10 v, � 20% (3528 ? 21) c2 kemet t491b475k010as 10 1 chip capacitor 0.1 � f/10 v, � 10% (0402) c3 panasonic ecj0eb1a104k 11 1 chip capacitor 15 nf/16 v, � 10% (0402) c4 panasonic ecj0eb1c153k 12 1 chip capacitor 4.7 � f/25 v, � 20% (0805) c5 panasonic ecj2fb1e475m 13 1 smt chip led red d1 agilent hsmh ? c150 14 1 smt chip led green d2 agilent hsmg ? c150 15 1 smt chip led y ellow d4 agilent hsmy ? c150 16 5 test pin t1, t2, t7, t8, t9, t10 amp/tyco 4 ? 103747 ? 0 17 2 header pin pinch = 2.54 mm jp1, jp2 amp/tyco 4 ? 103747 ? 0
ncp1835 http://onsemi.com 16 package dimensions dfn 3x3 mn suffix case 485c ? 01 issue o x m 0.10 (0.004) t dim min max min max inches millimeters a 3.00 bsc 0.118 bsc b 3.00 bsc 0.118 bsc c 0.80 1.00 0.031 0.039 d 0.20 0.30 0.008 0.012 g 0.50 bsc 0.020 bsc h 1.23 1.28 0.048 0.050 j 0.20 ref 0.008 ref k 0.00 0.05 0.000 0.002 l 0.35 0.45 0.014 0.018 notes: 1. dimensioning and tolerancing per ansi y14.5m, 1982. 2. controlling dimension: millimeters. 3. dimension d applies to plated terminal and is measured between 0.25 and 0.30 mm from terminal. 4. coplanarity applies to the exposed pad as well as the terminals. ? t ? ? x ? note 3 seating plane l a m ? y ? b n 0.25 (0.010) t 0.25 (0.010) t j c k r g e h f p d y 10 1 e 2.45 2.55 0.096 0.100 f 1.75 1.85 0.069 0.073 m 1.50 bsc 0.059 bsc n 1.50 bsc 0.059 bsc p 0.88 0.93 0.035 0.037 r 0.60 0.80 0.024 0.031 2 pl 2 pl 10 pl 0.280 0.011 � mm inches � scale 10:1 0.630 0.025 2.50 0.098 3.31 0.130 1.65 0.065 0.500 0.0196 *for additional information on our pb ? free strategy and soldering details, please download the on semiconductor soldering and mounting t echniques reference manual, solderrm/d. soldering footprint* on semiconductor and are registered trademarks of semiconductor components industries, llc (scillc). scillc reserves the right to mak e changes without further notice to any products herein. scillc makes no warranty, representation or guarantee regarding the suitability of its products for an y particular purpose, nor does scillc assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, in cluding without limitation special, consequential or incidental damages. ?typical? parameters which may be provided in scillc data sheets and/or specifications can and do vary in different a pplications and actual performance may vary over time. all operating parameters, including ?typicals? must be validated for each customer application by customer?s technical e xperts. scillc does not convey any license under its patent rights nor the rights of others. scillc products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the scillc prod uct could create a s ituation where personal injury or death may occur. should buyer purchase or use scillc products for any such unintended or unauthorized application, buyer shall indem nify and hold scillc and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney f ees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that scillc was neglig ent regarding the design or manufacture of the part. scillc is an equal opportunity/affirmative action employer. this literature is subject to all applicable copyright laws and is not for resale in any manner. publication ordering information n. american technical support : 800 ? 282 ? 9855 toll free usa/canada japan : on semiconductor, japan customer focus center 2 ? 9 ? 1 kamimeguro, meguro ? ku, tokyo, japan 153 ? 0051 phone : 81 ? 3 ? 5773 ? 3850 ncp1835/d literature fulfillment : literature distribution center for on semiconductor p.o. box 61312, phoenix, arizona 85082 ? 1312 usa phone : 480 ? 829 ? 7710 or 800 ? 344 ? 3860 toll free usa/canada fax : 480 ? 829 ? 7709 or 800 ? 344 ? 3867 toll free usa/canada email : orderlit@onsemi.com on semiconductor website : http://onsemi.com order literature : http://www.onsemi.com/litorder for additional information, please contact your local sales representative.
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