? 2005-2013 microchip technology inc. ds20001826c-page 1 mcp1700 features: 1.6 a typical quiescent current input operating voltage range: 2.3v to 6.0v output voltage range: 1.2v to 5.0v 250 ma output current for output voltages ? 2.5v 200 ma output current for output voltages < 2.5v low dropout (ldo) voltage - 178 mv typical @ 250 ma for v out =2.8v 0.4% typical output voltage tolerance standard output voltage options: - 1.2v, 1.8v, 2.5v, 2.8v, 3.0v, 3.3v, 5.0v stable with 1.0 f ceramic output capacitor short circuit protection overtemperature protection applications: battery-powered devices battery-powered alarm circuits smoke detectors co 2 detectors pagers and cellular phones smart battery packs low quiescent current voltage reference pdas digital cameras microcontroller power related literature: an765, ?using microchip?s micropower ldos? (ds00765), microchip technology inc., 2002 an766, ?pin-compatible cmos upgrades to bipolar ldos? (ds00766), microchip technology inc., 2002 an792, ?a method to determine how much power a sot23 can dissipate in an application? (ds00792), microchip technology inc., 2001 general description: the mcp1700 is a family of cmos low dropout (ldo) voltage regulators that can deliver up to 250 ma of current while consuming only 1.6 a of quiescent current (typical). the input operating range is specified from 2.3v to 6.0v, making it an ideal choice for two and three primary cell battery-powered applications, as well as single cell li-ion-powered applications. the mcp1700 is capable of delivering 250 ma with only 178 mv of input to output voltage differential (v out = 2.8v). the output voltage tolerance of the mcp1700 is typically 0.4% at +25c and 3% maximum over the operating junction temperature range of -40c to +125c. output voltages available for the mcp1700 range from 1.2v to 5.0v. the ldo output is stable when using only 1 f output capacitance. ceramic, tantalum or aluminum electrolytic capacitors can all be used for input and output. overcurrent limit and overtemperature shutdown provide a robust solution for any application. package options include sot-23, sot-89, to-92 and 2x2 dfn-6. package types 1 3 2 v in gnd v out mcp1700 1 2 3 v in gnd v out mcp1700 3-pin sot-23 3-pin sot-89 3 2 1 gnd v in v out mcp1700 3-pin to-92 v in v in 1 2 3 ep 7 * includes exposed thermal pad (ep); see table 3-1 . 6 5 4 nc gnd nc nc v out 2x2 dfn-6* low quiescent current ldo downloaded from: http:///
mcp1700 ds20001826c-page 2 ? 2005-2013 microchip technology inc. functional block diagrams typical application circuits + - v in v out gnd +v in error amplifier voltage reference overcurrent overtemperature mcp1700 gnd v out v in c in 1f ceramic c out 1f ceramic v out v in (2.3v to 3.2v) 1.8v i out 150 ma mcp1700 downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 3 mcp1700 1.0 electrical characteristics absolute maximum ratings ? v dd ............................................................................................+ 6.5v all inputs and outputs w.r.t. ......... (v ss - 0.3v) to (v in +0.3v) peak output current ....................................internally limited storage temperature .....................................-65c to +150c maximum junction temperature ................................... 150c operating junction temperature...................-40c to +125c esd protection on all pins (hbm;mm) ??????????????? ? 4kv; ? 400v ? notice: stresses above those listed under maximum ratings may cause permanent damage to the device. this is a stress rating only and functional operation of the device at those or any other conditions above those indicated in the operational listings of this s pecification is not implied. exposure to maximum rating conditions for extended periods may affect device reliability. dc characteristics electrical characteristics: unless otherwise specified, al l limits are established for v in =v r +1v, i load = 100 a, c out = 1 f (x7r), c in = 1 f (x7r), t a = +25c. boldface type applies for junction temperatures, t j ( note 6 ) of -40c to +125c. parameters sym. min. typ. max. units conditions input / output characteristics input operating voltage v in 2.3 6.0 v note 1 input quiescent current i q 1 . 6 4 a i l =0ma, v in =v r +1v maximum output current i out_ma 250200 ma for v r ? 2.5v for v r ? 2.5v output short circuit current i out_sc 4 0 8m av in =v r +1v, v out =gnd current (peak current) measured 10 ms after short is applied. output voltage regulation v out v r -3.0% v r -2.0% v r 0.4% v r +3.0% v r +2.0% v note 2 v out temperature coefficient tcv out 5 0p p m / c note 3 line regulation ? v out / (v out x ? v in ) -1.0 0.75 +1.0 %/v (v r +1)v ? v in ? 6v load regulation ? v out /v out -1.5 1.0 +1.5 %i l = 0.1 ma to 250 ma for v r ? 2.5v i l = 0.1 ma to 200 ma for v r ? 2.5v note 4 dropout voltage v r ? 2.5v v in -v out 1 7 8 350 mv i l = 250 ma, ( note 1 , note 5 ) dropout voltage v r ? 2.5v v in -v out 1 5 0 350 mv i l = 200 ma, ( note 1 , note 5 ) output rise time t r 500 s 10% v r to 90% v r v in = 0v to 6v, r l =50 ? resistive note 1: the minimum v in must meet two conditions: v in ? 2.3v and v in ?? ? v r +3.0% ?? v dropout . 2: v r is the nominal regulator output voltage. for example: v r = 1.2v, 1.5v, 1.8v, 2.5v, 2.8v, 3.0v, 3.3v, 4.0v, 5.0v. the input voltage v in =v r + 1.0v; i out = 100 a. 3: tcv out =(v out-high -v out-low ) *10 6 / (v r * ? temperature), v out-high = highest voltage measured over the temperature range. v out-low = lowest voltage measured ov er the temperature range. 4: load regulation is measured at a constant junction temperature using low duty cycle pulse testing. changes in output voltage due to heating effects are determined using thermal regulation specification tcv out . 5: dropout voltage is defined as the input to output differentia l at which the output voltage drops 2% below its measured value with a v r + 1v differential applied. 6: the maximum allowable power dissipation is a function of ambient temperature, the maximum allowable junction temperature and the thermal resistance from junction to air (i.e., t a , t j , ? ja ). exceeding the maximum allowable power dissipation will cause the device operating junction temperature to exceed the maximum 150c rating. sustained junction temperatures above 150c can impact the device reliability. 7: the junction temperature is approximated by soaking the dev ice under test at an ambient temperature equal to the desired junction temperature. the test time is small enough such that the rise in the junction temperature over the ambient temperature is not significant. downloaded from: http:///
mcp1700 ds20001826c-page 4 ? 2005-2013 microchip technology inc. output noise e n 3 v / ( h z ) 1/2 i l = 100 ma, f = 1 khz, c out =1f power supply ripple rejection ratio psrr 44 db f = 100 hz, c out =1f, i l =50ma, v inac = 100 mv pk-pk, c in =0f, v r =1.2v thermal shutdown protection t sd 140 c v in =v r +1v, i l = 100 a temperature specifications electrical characteristics: unless otherwise specified, al l limits are established for v in =v r +1v, i load = 100 a, c out = 1 f (x7r), c in = 1 f (x7r), t a = +25c. boldface type applies for junction temperatures, t j ( note 1 ) of -40c to +125c. parameters sym. min. typ. max. units conditions temperature ranges specified temperature range t a -40 +125 c operating temperature range t j -40 +125 c storage temperature range t a -65 +150 c thermal package resistance thermal resistance, 2x2 dfn ? ja 9 1 c / w eia/jedec ? jesd51-7 fr-4 0.063 4-layer board ? jc 1 9 c / w thermal resistance, sot-23 ? ja 336 c/w eia/jedec jesd51-7 fr-4 0.063 4-layer board ? jc 1 1 0 c / w thermal resistance, sot-89 ? ja 180 c/w eia/jedec jesd51-7 fr-4 0.063 4-layer board ? jc 5 2 c / w thermal resistance, to-92 ? ja 160 c/w ? jc 66.3 c/w note 1: the maximum allowable power dissipation is a function of ambient temperature, the maximum allowable junction temperature and the thermal resistance from junction to air (i.e., t a , t j , ? ja ). exceeding the maximum allowable power dissipation will cause the device operating junction temper ature to exceed the maximum 150c rating. sustained junction temperatures above 150c can impact the device reliability. dc characteristics (continued) electrical characteristics: unless otherwise specified, al l limits are established for v in =v r +1v, i load = 100 a, c out = 1 f (x7r), c in = 1 f (x7r), t a = +25c. boldface type applies for junction temperatures, t j ( note 6 ) of -40c to +125c. parameters sym. min. typ. max. units conditions note 1: the minimum v in must meet two conditions: v in ? 2.3v and v in ?? ? v r +3.0% ?? v dropout . 2: v r is the nominal regulator output voltage. for example: v r = 1.2v, 1.5v, 1.8v, 2.5v, 2.8v, 3.0v, 3.3v, 4.0v, 5.0v. the input voltage v in =v r + 1.0v; i out = 100 a. 3: tcv out =(v out-high -v out-low ) *10 6 / (v r * ? temperature), v out-high = highest voltage measured over the temperature range. v out-low = lowest voltage measured ov er the temperature range. 4: load regulation is measured at a constant junction temperature using low duty cycle pulse testing. changes in output voltage due to heating effects are determined using thermal regulation specification tcv out . 5: dropout voltage is defined as the input to output differentia l at which the output voltage drops 2% below its measured value with a v r + 1v differential applied. 6: the maximum allowable power dissipation is a function of ambient temperature, the maximum allowable junction temperature and the thermal resistance from junction to air (i.e., t a , t j , ? ja ). exceeding the maximum allowable power dissipation will cause the device operating junction temperature to exceed the maximum 150c rating. sustained junction temperatures above 150c c an impact the device reliability. 7: the junction temperature is approximated by soaking the dev ice under test at an ambient temperature equal to the desired junction temperature. the test time is small enough su ch that the rise in the junction temperature over the ambient temperature is not significant. downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 5 mcp1700 2.0 typical performance curves note: unless otherwise indicated: v r =1.8v, c out = 1 f ceramic (x7r), c in = 1 f ceramic (x7r), i l =100a, t a =+25c, v in =v r +1v. note: junction temperature (t j ) is approximated by soaking the device under test to an ambient temperature equal to the desired junction temperature. the test time is small enough such that the rise in junction temperature over the ambient temperature is not signi ficant. figure 2-1: input quiescent current vs. input voltage. figure 2-2: ground current vs. load current. figure 2-3: quiescent current vs. junction temperature. figure 2-4: output voltage vs. input voltage (v r =1.2v). figure 2-5: output voltage vs. input voltage (v r =1.8v). figure 2-6: output voltage vs. input voltage (v r =2.8v). note: the graphs and tables provided following this note are a statistical summary based on a limited number of samples and are provided for informational purposes only. the performance characteristics listed herein are not tested or guaranteed. in some graphs or tables, the data presented may be outside the specified operating range (e.g., outside specified power supply range) and therefore outside the warranted range. 1.8 2.0 2.2 2.4 2.6 2.8 3.0 s cent current (a) t j = - 40c t j = +25c t j = +125c v r = 1.2v i out = 0 a 1.0 1.2 1.4 1.6 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 quie s input voltage (v) 20 25 30 35 40 45 50 u nd current (a) v r = 2.8v t j = - 40c t j = +25c t j = +125c 0 5 10 15 0 25 50 75 100 125 150 175 200 225 250 gro u load current (ma) 1.75 2.00 2.25 2.50 c ent current (a) v r = 5.0v v r = 1.2v v in = v r + 1v i out = 0 a 1.25 1.50 -40-25-10 5 203550658095110125 quies c junction temperature (c) v r = 2.8v 1.196 1.198 1.200 1.202 1.204 1.206 1.208 u tput voltage (v) t j = +25c t j = +125c v r = 1.2v i out = 0.1 ma 1.190 1.192 1.194 1.196 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 o u input voltage (v) t j = - 40c 1 780 1.785 1.790 1.795 1.800 p ut voltage (v) t j = - 40c t j = +125c v r = 1.8v i out = 0.1 ma 1.770 1.775 1 . 780 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 out p input voltage (v) t j = +25c 2.786 2.788 2.790 2.792 2.794 2.796 2.798 2.800 u tput voltage (v) t j = - 40c t j = +25c v r = 2.8v i out = 0.1 ma 2.778 2.780 2.782 2.784 3.3 3.6 3.9 4.2 4.5 4.8 5.1 5.4 5.7 6.0 o u input voltage (v) t j = +125c downloaded from: http:///
mcp1700 ds20001826c-page 6 ? 2005-2013 microchip technology inc. note: unless otherwise indicated: v r =1.8v, c out = 1 f ceramic (x7r), c in = 1 f ceramic (x7r), i l =100a, t a =+25c, v in =v r +1v. figure 2-7: output voltage vs. input voltage (v r =5.0v). figure 2-8: output voltage vs. load current (v r =1.2v). figure 2-9: output voltage vs. load current (v r =1.8v). figure 2-10: output voltage vs. load current (v r =2.8v). figure 2-11: output voltage vs. load current (v r =5.0v). figure 2-12: dropout voltage vs. load current (v r =2.8v). 4.970 4.975 4.980 4.985 4.990 4.995 5.000 tput voltage (v) t j = - 40c t j = +25c v r = 5.0v i out = 0.1 ma 4.955 4.960 4.965 4.970 5.0 5.2 5.4 5.6 5.8 6.0 ou input voltage (v) t j = +125c 1.17 1.18 1.19 1.20 1.21 tput voltage (v) t j = - 40c t j = +25c t j = +125 c v r = 1.2v v in = v r + 1v 1.15 1.16 1.17 0 25 50 75 100 125 150 175 200 ou load current (ma) t j +125 c 1.784 1.786 1.788 1.790 1.792 u tput voltage (v) t j = - 40c t j = +25c t j = +125c 1.778 1.780 1.782 0 25 50 75 100 125 150 175 200 o u load current (ma) v r = 1.8v v in = v r + 1v 2 784 2.786 2.788 2.790 2.792 2.794 2.796 2.798 u tput voltage (v) t j = - 40c t j = +25c v r = 2.8v v in = v r + 1v 2.778 2.780 2.782 2 . 784 0 50 100 150 200 250 o u load current (ma) t j = +125c 4 970 4.975 4.980 4.985 4.990 4.995 5.000 tput voltage (v) t j = - 40c t j = +25c v r = 5.0v v in = v r + 1v 4.955 4.960 4.965 4 . 970 0 50 100 150 200 250 ou load current (ma) t j = +125c 0.10 0.15 0.20 0.25 p out votage (v) t = 40 c t j = +25c t j = +125c v r = 2.8v 0.00 0.05 0 25 50 75 100 125 150 175 200 225 250 dro p load current (ma) t j = - 40 c downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 7 mcp1700 note: unless otherwise indicated: v r =1.8v, c out = 1 f ceramic (x7r), c in = 1 f ceramic (x7r), i l =100a, t a =+25c, v in =v r +1v. figure 2-13: dropout voltage vs. load current (v r =5.0v). figure 2-14: power supply ripple rejection vs. frequency (v r =1.2v). figure 2-15: power supply ripple rejection vs. frequency (v r =2.8v). figure 2-16: noise vs. frequency. figure 2-17: dynamic load step (v r =1.2v). figure 2-18: dynamic load step (v r =1.8v). 0.06 0.08 0.10 0.12 0.14 0.16 o ut voltage (v) t j = +25c t j = +125c v r = 5.0v 0.00 0.02 0.04 0 25 50 75 100 125 150 175 200 225 250 drop o load current (ma) t j = - 40c 0.01 0.1 0 10.0 100 1000 1.0 0 frequency ( �k h) psrr (db/decade) 0 -10 -20-30 -40 -50 +10 +20 -60 -70 0.01 0.01 10. 0 0 100 1000 frequency ( �k h) psrr (db/decade) +20 +10 0 -10 -20-30 -40 -50 -60 1 ������ 010 1.00 10.00 n oise (v/ hz) v in = 2.5v v r = 1.2v i out = 50 ma v in = 2.8v v r = 1.8v i out = 50 ma v in = 3.8v v r = 2.8v i out = 50 ma 0.01 0 . 10 0.01 0.1 1 10 100 1000 n frequency (khz) v in =2.2v v r =1.2v i=100ma load step c in =1f ceramic c out = 1f ceramic v in =2.8v v r =1.8v i=100ma load step c in =1f ceramic c out = 1f ceramic downloaded from: http:///
mcp1700 ds20001826c-page 8 ? 2005-2013 microchip technology inc. note: unless otherwise indicated: v r =1.8v, c out = 1 f ceramic (x7r), c in = f ceramic (x7r), i l =100a, t a =+25c, v in =v r +1v. figure 2-19: dynamic load step (v r =2.8v) . figure 2-20: dynamic load step (v r =1.8v) . figure 2-21: dynamic load step (v r =2.8v) . figure 2-22: dynamic load step (v r =5.0v) . figure 2-23: dynamic line step (v r =2.8v) . figure 2-24: start-up from v in (v r =1.2v). v in =3.8v v r =2.8v i=100ma load step c in = 1f ceramic c out = 1f ceramic v in =2.8v v r =1.8v i out = 200 ma load step c in = 1 f ceramic c out =22f (1 ? esr) v in =3.8v v r =2.8v i out =200ma load step c out =22f (1 ? esr) c in =1f ceramic v in =6v v r =5v i out = 200 ma load step c out =22f (1 ? esr) c in = 1 f ceramic v in =3.8v to 4.8v v r =2.8v i out 100 ma c out =1f ceramic v in =0v to 2.2v v r =1.2v c out = 1 f ceramic r load =25 ? downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 9 mcp1700 note: unless otherwise indicated: v r =1.8v, c out = 1 f ceramic (x7r), c in = 1 f ceramic (x7r), i l =100a, t a =+25c, v in =v r +1v. figure 2-25: start-up from v in (v r =1.8v). figure 2-26: start-up from v in (v r =2.8v). figure 2-27: load regulation vs. junction temperature (v r =1.8v). figure 2-28: load regulation vs. junction temperature (v r =2.8v). figure 2-29: load regulation vs. junction temperature (v r =5.0v). figure 2-30: line regulation vs. temperature (v r = 1.2v, 1.8v, 2.8v). v in =0v to 2.8v v r =1.8v c out = 1 f ceramic r load =25 ? v in =0v to 3.8v v r =2.8v c out = 1 f ceramic r load =25 ? 02 -0.1 0.0 0.1 0.2 0.3 a d regulation (%) v r = 1.8v i out = 0 to 200 ma v in = 5.0v v in = 3.5v -0.4 -0.3 - 0 . 2 -40 -25 -10 5 20 35 50 65 80 95 110 125 lo a junction temperature (c) v in = 2.2v -0.4 -0.3 -0.2 -0.1 0.0 a d regulation (%) v r = 2.8v i out = 0 to 250 ma v in = 5.0v v in = 4.3v v in = 3.3 v -0.7 -0.6 -0.5 -40 -25 -10 5 20 35 50 65 80 95 110 125 lo a junction temperature (c) in 010 -0.05 0.00 0.05 0.10 d regulation (%) v r = 5.0v i out = 0 to 250 ma v in = 5 . 5v v in = 6.0v -0.20 -0.15 - 0 . 10 -40 -25 -10 5 20 35 50 65 80 95 110 125 loa d junction temperature (c) in 55 -0.15 -0.10 -0.05 0.00 0.05 0.10 regulation (%/v) v r = 1.8v v r = 2.8v -0.30 -0.25 -0.20 -40 -25 -10 5 20 35 50 65 80 95 110 125 line junction temperature (c) v r = 1.2v downloaded from: http:///
mcp1700 ds20001826c-page 10 ? 2005-2013 microchip technology inc. 3.0 pin descriptions the descriptions of the pins are listed in tab l e 3 - 1 . 3.1 ground terminal (gnd) regulator ground. tie gnd to the negative side of the output and the negative side of the input capacitor. only the ldo bias current (1.6 a typical) flows out of this pin; there is no high current. the ldo output regulation is referenced to this pin. minimize voltage drops between this pin and the negative side of the load. 3.2 regulated output voltage (v out ) connect v out to the positive side of the load and the positive terminal of the output capacitor. the positive side of the output capacitor should be physically located as close to the ldo v out pin as is practical. the current flowing out of this pin is equal to the dc load current. 3.3 unregulated input voltage pin (v in ) connect v in to the input unregulated source voltage. as with all low dropout linear regulators, low source impedance is necessary for the stable operation of the ldo. the amount of capacitance required to ensure low source impedance will depend on the proximity of the input source capacitors or battery type. for most applications, 1 f of capacitance will ensure stable operation of the ldo circuit. for applications that have load currents below 100 ma, the input capacitance requirement can be lowered. the type of capacitor used can be ceramic, tantalum or aluminum electrolytic. the low esr characteristics of the ceramic will yield better noise and psrr performance at high frequency. 3.4 no connect (nc) no internal connection. the pins marked nc are true no connect pins. 3.5 exposed thermal pad (ep) there is an internal electrical connection between the exposed thermal pad (ep) and the gnd pin; they must be connected to the same potential on the printed circuit board (pcb). table 3-1: pin function table pin no. sot-23 pin no. sot-89 pin no. to-92 pin no. 2x2 dfn-6 name function 1 1 1 3 gnd ground terminal 233 6v out regulated voltage output 322 1 v in unregulated supply voltage 2, 4, 5 nc no connect 7 ep exposed thermal pad downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 11 mcp1700 4.0 detailed description 4.1 output regulation a portion of the ldo output voltage is fed back to the internal error amplifier and compared with the precision internal bandgap reference. the error amplifier output will adjust the amount of current that flows through the p-channel pass transistor, thus regulating the output voltage to the desired value. any changes in input voltage or output current will cause the error amplifier to respond and adjust the output voltage to the target voltage (refer to figure 4-1 ). 4.2 overcurrent the mcp1700 internal circuitry monitors the amount of current flowing through the p-channel pass transistor. in the event of a short circuit or excessive output current, the mcp1700 will turn off the p-channel device for a short period, after which the ldo will attempt to restart. if the excessive current remains, the cycle will repeat itself. 4.3 overtemperature the internal power dissipation within the ldo is a function of input-to-output voltage differential and load current. if the power dissipation within the ldo is excessive, the internal junction temperature will rise above the typical shutdown threshold of 140c. at that point, the ldo will shut down and begin to cool to the typical turn-on junction temperature of 130c. if the power dissipation is low enough, the device will continue to cool and operate normally. if the power dissipation remains high, the thermal shutdown protection circuitry will again turn off the ldo, protecting it from catastrophic failure. figure 4-1: block diagram. + - v in v out gnd +v in error amplifier voltage reference overcurrent overtemperature mcp1700 downloaded from: http:///
mcp1700 ds20001826c-page 12 ? 2005-2013 microchip technology inc. 5.0 functional description the mcp1700 cmos low dropout linear regulator is intended for applications that need the lowest current consumption while maintaining output voltage regulation. the operating continuous load of the mcp1700 ranges from 0 ma to 250 ma (v r ? 2.5v). the input operating voltage ranges from 2.3v to 6.0v, making it capable of operating from two, three or four alkaline cells or a single li-ion cell battery input. 5.1 input the input of the mcp1700 is connected to the source of the p-channel pmos pass transistor. as with all ldo circuits, a relatively low source impedance (10 ? ) is needed to prevent the input impedance from causing the ldo to become unstable. the size and type of the required capacitor depend heavily on the input source type (battery, power supply) and the output current range of the application. for most applications (up to 100 ma), a 1 f ceramic capacitor will be sufficient to ensure circuit stability. larger values can be used to improve circuit ac performance. 5.2 output the maximum rated continuous output current for the mcp1700 is 250 ma (v r ? 2.5v). for applications where v r < 2.5v, the maximum output current is 200 ma. a minimum output capacitance of 1.0 f is required for small signal stability in applications that have up to 250 ma output current capability. the capacitor type can be ceramic, tantalum or aluminum electrolytic. the esr range on the output capacitor can range from 0 ? to 2.0 ? . 5.3 output rise time when powering up the internal reference output, the typical output rise time of 500 s is controlled to prevent overshoot of the output voltage. downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 13 mcp1700 6.0 application circuits and issues 6.1 typical application the mcp1700 is most commonly used as a voltage regulator. its low quiescent current and low dropout voltage make it ideal for many battery-powered applications. figure 6-1: typical application circuit. 6.1.1 application input conditions 6.2 power calculations 6.2.1 power dissipation the internal power dissipation of the mcp1700 is a function of input voltage, output voltage and output current. the power dissipation resulting from the quiescent current draw is so low it is insignificant (1.6 a x v in ). the following equation can be used to calculate the internal power dissipation of the ldo. equation 6-1: the maximum continuous operating junction temperature specified for the mcp1700 is +125 c . to estimate the internal junction temperature of the mcp1700, the total internal power dissipation is multiplied by the thermal resistance from junction to ambient (r ? ja ). the thermal resistance from junction to ambient for the sot-23 pin package is estimated at 230 c/w. equation 6-2: the maximum power dissipation capability for a package can be calculated given the junction-to- ambient thermal resistance and the maximum ambient temperature for the application. the following equation can be used to determine the maximum internal power dissipation of the package. equation 6-3: equation 6-4: package type = sot-23 input voltage range = 2.3v to 3.2v v in maximum = 3.2v v out typical = 1.8v i out = 150 ma maximum gnd v out v in c in 1f ceramic c out 1f ceramic v out v in (2.3v to 3.2v) 1.8v i out 150 ma mcp1700 p ldo v in max ?? v out min ?? ? ?? i out max ?? ? = p ldo = internal power dissipation of the ldo pass device v in(max) = maximum input voltage v out(min) = minimum output voltage of the ldo t jmax ?? p total r ? ja ? t amax ?? + = t j(max) = maximum continuous junction temperature p total = total power dissipation of the device r ? ja = thermal resistance from junction to ambient t a(max) = maximum ambient temperature p dmax ?? t jmax ?? t amax ?? ? ?? r ? ja --------------------------------------------------- = p d(max) = maximum power dissipation of the device t j(max) = maximum continuous junction temperature t a(max) = maximum ambient temperature r ? ja = thermal resistance from junction to ambient t jrise ?? p dmax ?? r ? ja ? = t j(rise) = rise in the devices junction temperature over the ambient temperature p total = maximum power dissipation of the device r ? ja = thermal resistance from junction to ambient downloaded from: http:///
mcp1700 ds20001826c-page 14 ? 2005-2013 microchip technology inc. equation 6-5: 6.3 voltage regulator internal power dissipation, junction temperature rise, junction temperature and maximum power dissipation are calculated in the following example. the power dissipation resulting from ground current is small enough to be neglected. 6.3.1 power dissipation example device junction temperature rise the internal junction temperature rise is a function of internal power dissipation and the thermal resistance from junction to ambient for the application. the thermal resistance from junction to ambient (r ? ja ) is derived from an eia/jedec ? standard for measuring thermal resistance for small surface mount packages. the eia/ jedec specification is jesd51-7, ?high effective thermal conductivity test board for leaded surface mount packages? . the standard describes the test method and board specifications for measuring the thermal resistance from junction to ambient. the actual thermal resistance for a particular application can vary depending on many factors, such as copper area and thickness. refer to an792, ?a method to determine how much power a sot-23 can dissipate in an application? (ds00792), for more information regarding this subject. junction temperature estimate to estimate the internal junction temperature, the calculated temperature rise is added to the ambient or offset temperature. for this example, the worst-case junction temperature is estimated below. maximum package power dissipation at +40c ambient temperature package package type = sot-23 input voltage v in = 2.3v to 3.2v ldo output voltages and currents v out = 1.8v i out =150ma maximum ambient temperature t a(max) = +40c internal power dissipation internal power dissipation is the product of the ldo output current times the voltage across the ldo (v in to v out ). p ldo(max) =(v in(max) -v out(min) )xi out(max) p ldo = (3.2v - (0.97 x 1.8v)) x 150 ma p ldo = 218.1 milli-watts t j t jrise ?? t a + = t j = junction temperature t j(rise) = rise in the devices junction temperature over the ambient temperature t a = ambient temperature t j(rise) =p total xr ? ja t j(rise) = 218.1 milli-watts x 230.0 c/watt t j(rise) =50.2 c t j =t j(rise) +t a(max) t j =90.2c 2x2 dfn-6 (91c/watt = r ? ja ) p d(max) = (125c - 40c) / 91c/w p d(max) = 934 milli-watts sot-23 (230.0c/watt = r ? ja ) p d(max) = (125c - 40c) / 230c/w p d(max) = 369.6 milli-watts sot-89 (52c/watt = r ? ja ) p d(max) = (125c - 40c) / 52c/w p d(max) = 1.635 watts to-92 (131.9c/watt = r ? ja ) p d(max) = (125c - 40c) / 131.9c/w p d(max) = 644 milli-watts downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 15 mcp1700 6.4 voltage reference the mcp1700 can be used not only as a regulator, but also as a low quiescent current voltage reference. in many microcontroller applications, the initial accuracy of the reference can be calibrated using production test equipment or by using a ratio measurement. when the initial accuracy is calibrated, the thermal stability and line regulation tolerance are the only errors introduced by the mcp1700 ldo. the low cost, low quiescent current and small ceramic output capacitor are all advantages when using the mcp1700 as a voltage reference. figure 6-2: using the mcp1700 as a voltage reference. 6.5 pulsed load applications for some applications, there are pulsed load current events that may exceed the specified 250 ma maximum specification of the mcp1700. the internal current limit of the mcp1700 will prevent high peak load demands from causing non-recoverable damage. the 250 ma rating is a maximum average continuous rating. as long as the average current does not exceed 250 ma, pulsed higher load currents can be applied to the mcp1700 . the typical current limit for the mcp1700 is 550 ma (t a +25c). pic ? gnd v in c in 1f c out 1f bridge sensor v out v ref ad0 ad1 ratio metric reference 1 a bias microcontroller mcp1700 downloaded from: http:///
mcp1700 ds20001826c-page 16 ? 2005-2013 microchip technology inc. 7.0 packaging information 7.1 package marking information 3-pin sot-23 cknn 3-pin sot-89 cuyyww nnn 3-pin to-92 xxxxxxxxxxxx ywwnnn standard extended temp symbol voltage * ck 1.2 cm 1.8 cp 2.5 cq 2.8 cr 3.0 cs 3.3 cu 5.0 example 1700 1202e 322256 * custom output voltages available upon request. contact your local microchip sales office for more information. xxxxxx to^^ legend: xx...x customer-specific information y year code (last digit of calendar year) yy year code (last 2 digits of calendar year) ww week code (week of january 1 is week 01) nnn alphanumeric traceability code pb-free jedec ? designator for matte tin (sn) * this package is pb-free. the pb-free jedec designator ( ) can be found on the outer packaging for this package. note : in the event the full microchip part number cannot be marked on one line, it will be carried over to the next line, thus limiting the number of available characters for customer-specific information. 3 e 3 e 3 e 6-lead dfn (2x2x0.9 mm) example abb 256 part number code mcp1700t-1202e/may abb mcp1700t-1802e/may abc mcp1700t-2502e/may abd mcp1700t-2802e/may abf mcp1700t-3002e/may abe mcp1700t-3302e/may aaz mcp1700t-5002e/may aba downloaded from: http:///
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? 2005-2013 microchip technology inc. ds20001826c-page 25 mcp1700 appendix a: revision history revision c (october 2013) the following is the list of modifications: 1. added new package to the family (2x2 dfn-6) and related information throughout the document. 2. updated thermal package resistance information in temperature specifications . 3. updated section 3.0, pin descriptions . 4. added package markings and drawings for the 2x2 dfn-6 package. 5. added information related to the 2.8v option throughout the document. 6. updated product identification system . 7. minor typographical changes. revision b (february 2007) updated packaging information. corrected product identification system . changed x5r to x7r in notes to dc characteristics , temperature specifications , and section 2.0, typical performance curves . revision a (november 2005) original release of this document. downloaded from: http:///
mcp1700 ds20001826c-page 26 ? 2005-2013 microchip technology inc. product identification system to order or obtain information, e. g., on pricing or delivery, refer to the factory or the listed sales office . device: mcp1700: low quiescent current ldo tape and reel: t: tape and reel only applies to sot-23 and sot-89 devices standard output voltage: * 120 = 1.2v 180 = 1.8v 250 = 2.5v 280 = 2.8v 300 = 3.0v 330 = 3.3v 500 = 5.0v * custom output voltages available upon request. contact your local microchip sales office for more information tolerance: 2=2% temperature range: e = -40c to +125c (extended) package: may = plastic small outline transistor (dfn), 6-lead mb = plastic small outline transistor (sot-89), 3-lead to = plastic small outline transistor (to-92), 3-lead tt = plastic small outline transistor (sot-23), 3-lead examples: 2x2 dfn-6 package: a) mcp1700t-1202e/may:1.2v v out b) mcp1700t-1802e/may:1.8v v out c) mcp1700t-2502e/may:2.5v v out d) mcp1700t-2802e/may:2.8v v out e) mcp1700t-3002e/may:3.0v v out f) mcp1700t-3302e/may:3.3v v out g) mcp1700t-5002e/may:5.0v v out sot-89 package: a) mcp1700t-1202e/mb:1.2v v out b) mcp1700t-1802e/mb:1.8v v out c) mcp1700t-2502e/mb:2.5v v out d) mcp1700t-2802e/mb:2.8v v out e) mcp1700t-3002e/mb:3.0v v out f) mcp1700t-3302e/mb:3.3v v out g) mcp1700t-5002e/mb:5.0v v out to-92 package: a) mcp1700-1202e/to:1.2v v out b) mcp1700-1802e/to:1.8v v out c) mcp1700-2502e/to:2.5v v out d) mcp1700-2802e/to:2.8v v out e) mcp1700-3002e/to:3.0v v out f) mcp1700-3302e/to:3.3v v out g) mcp1700-5002e/to:5.0v v out sot-23 package: a) mcp1700t-1202e/tt:1.2v v out b) mcp1700t-1802e/tt:1.8v v out c) mcp1700t-2502e/tt:2.5v v out d) mcp1700t-2802e/tt:2.8v v out e) mcp1700t-3002e/tt:3.0v v out f) mcp1700t-3302e/tt:3.3v v out g) mcp1700t-5002e/tt:5.0v v out part no. x- xxx voltage tape & reel mcp1700 x tolerance x temp. range /xx package output downloaded from: http:///
? 2005-2013 microchip technology inc. ds20001826c-page 27 information contained in this publication regarding device applications and the like is provided only for your convenience and may be superseded by updates. it is your responsibility to ensure that your application meets with your specifications. microchip makes no representations or warranties of any kind whether express or implied, written or oral, statutory or otherwise, related to the information, including but not limited to its condition, quality, performance, merchantability or fitness for purpose . microchip disclaims all liability arising from this information and its use. use of microchip devices in life support and/or safety applications is entirely at the buyers risk, and the buyer agrees to defend, indemnify and hold harmless microchip from any and all damages, claims, suits, or expenses resulting from such use. no licenses are conveyed, implicitly or otherwise, under any microchip intellectual property rights. trademarks the microchip name and logo, the microchip logo, dspic, flashflex, k ee l oq , k ee l oq logo, mplab, pic, picmicro, picstart, pic 32 logo, rfpic, sst, sst logo, superflash and uni/o are registered trademarks of microchip technology incorporated in the u.s.a. and other countries. filterlab, hampshire, hi-tech c, linear active thermistor, mtp, seeval and the embedded control solutions company are registered trademarks of microchip technology incorporated in the u.s.a. silicon storage technology is a registered trademark of microchip technology inc. in other countries. analog-for-the-digital age, app lication maestro, bodycom, chipkit, chipkit logo, codeguard, dspicdem, dspicdem.net, dspicworks, dsspeak, ecan, economonitor, fansense, hi-tide, in-circuit serial programming, icsp, mindi, miwi, mpasm, mpf, mplab certified logo, mplib, mplink, mtouch, omniscient code generation, picc, picc-18, picdem, picdem.net, pickit, pictail, real ice, rflab, select mode, sqi, serial quad i/o, total endurance, tsharc, uniwindriver, wiperlock, zena and z-scale are trademarks of microchip technology incorporated in the u.s.a. and other countries. sqtp is a service mark of microchip technology incorporated in the u.s.a. gestic and ulpp are registered trademarks of microchip technology germany ii gmbh & co. kg, a subsidiary of microchip technology inc., in other countries. all other trademarks mentioned herein are property of their respective companies. ? 2005-2013, microchip technology incorporated, printed in the u.s.a., all rights reserved. printed on recycled paper. isbn: 978-1-62077-526-4 note the following details of the code protection feature on microchip devices: microchip products meet the specification cont ained in their particular microchip data sheet. microchip believes that its family of products is one of the most secure families of its kind on the market today, when used i n the intended manner and under normal conditions. there are dishonest and possibly illegal methods used to breach the code protection feature. all of these methods, to our knowledge, require using the microchip products in a manner outside the operating specif ications contained in microchips data sheets. most likely, the person doing so is engaged in theft of intellectual property. microchip is willing to work with the customer who is concerned about the integrity of their code. neither microchip nor any other semiconduc tor manufacturer can guarantee the security of their code. code protection does not mean that we are guaranteeing the product as unbreakable. code protection is constantly evolving. we at microchip are co mmitted to continuously improvin g the code protection features of our products. attempts to break microchips code protection feature may be a violation of the digital millennium copyright act. if such acts allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that act. microchip received iso/ts-16949:2009 certification for its worldwide headquarters, design and wafer fabrication facilities in chandler and tempe, arizona; gresham, oregon and design centers in california and india. the company?s quality system processes and procedures are for its pic ? mcus and dspic ? dscs, k ee l oq ? code hopping devices, serial eeproms, microperipherals, nonvolatile memory an d analog products. in addition, microchip?s quality system for the design and manufacture of development systems is iso 9001:2000 certified. quality management s ystem certified by dnv == iso/ts 16949 == downloaded from: http:///
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