TAR5S15~tar5s50 2000-10-30 1/22 toshiba bipolar linear integrated circuit silicon monolithic TAR5S15, tar5s18, tar5s20, tar5s21, tar5s22, tar5s23, tar5s25, tar5s27, tar5s28, tar5s29, tar5s30, tar5s31, tar5s32, tar5s33, tar5s35, tar5s45, tar5s48, tar5s50 point regulators (low-dropout regulator) the tar5sxx series is comprised of general-purpose bipolar single-power-supply devices incorporating a control pin which can be used to turn them on/off. overtemperature and overcurrent protection circuits are built into the devices? output circuit. features ? low stand-by current ? overtemperature/overcurrent protection ? operation voltage range is wide. ? maximum output current is high. ? difference between input voltage and output voltage is low. ? small package. ? ceramic capacitors can be used. pin assignments (top view) overtemperature protection and overcurrent protection functions are not necessary guarantee of operating ratings below the maximum ratings. do not use devices under conditions in which their maximum ratings will be exceeded. weight: 0.014 g (typ.) 1 3 2 v in noise 4 gnd v out control 5 ? toshiba is continually working to improve the quality and reliability of its products. nevertheless, semiconductor devices in g eneral can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. it is the responsibi lity of th e buyer, when utilizing toshiba products, to comply with the standards of safety in making a safe design for the entire system, a nd to avoid situations in which a malfunction or failure of such toshiba products could cause loss of human life, bodily injury o r damage to property. in developing your designs, please ensure that toshiba products are used within specified operating ranges as set forth in th e most recent toshiba products specifications. also, please keep in mind the precautions and conditions set forth in the ?handlin g guide for semiconductor devices,? or ?toshiba semiconductor reliability handbook? etc.. ? the toshiba products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.). these toshiba products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfun ction o r failure of which may cause loss of human life or bodily injury (?unintended usage?). unintended usage include atomic energ y control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion cont rol instruments, medical instruments, all types of safety devices, etc.. unintended usage of toshiba products listed in this docume n t shall be made at the customer?s own risk. ? the products described in this document are subject to the foreign exchange and foreign trade laws. ? the information contained herein is presented only as a guide for the applications of our products. no responsibility is assume d b y toshiba corporation for any infringements of intellectual property or other rights of the third parties which may result from i ts use. no license is granted by implication or otherwise under any intellectual property or other rights of toshiba corporation o r others. ? the information contained herein is subject to change without notice. 000707 eba1
TAR5S15~tar5s50 2000-10-30 2/22 list of products number and marking marking on the product products no. marking TAR5S15 1v5 tar5s18 1v8 tar5s20 2v0 tar5s21 2v1 tar5s22 2v2 tar5s23 2v3 tar5s25 2v5 tar5s27 2v7 tar5s28 2v8 tar5s29 2v9 tar5s30 3v0 tar5s31 3v1 tar5s32 3v2 tar5s33 3v3 tar5s35 3v5 tar5s45 4v5 tar5s48 4v8 tar5s50 5v0 maximum ratings (ta = = = = 25c) characteristics symbol rating unit supply voltage v in 15 v output current i out 200 ma 200 (note1) power dissipation p d 380 (note2) mw operation temperature range t opr ? 40 to 85 c storage temperature range t stg ? 55 to 150 c note1: unit ratintg note2: mounted on a glass epoxy circuit board of 30 30 mm. pad dimension of 50 mm 2 3 v 0 example: tar5s30 (3.0 v output)
TAR5S15~tar5s50 2000-10-30 3/22 TAR5S15~tar5s22 electrical characteristic (unless otherwise specified, v in = = = = v out + + + + 1 v, i out = = = = 50 ma, c in = = = = 1 f, c out = = = = 10 f, c noise = = = = 0.01 f, t j = = = = 25c) characteristics symbol test condition min typ. max unit output voltage v out please refer to the output voltage accuracy table. line regulation reg �k line v out + 1 v < = v in < = 15 v, i out = 1 ma ? 3 15 mv load regulation reg �k load 1 ma < = i out < = 150 ma ? 25 75 mv i b1 i out = 0 ma ? 170 ? quiescent current i b2 i out = 50 ma ? 550 850 a stand-by current i b (off) v ct = 0 v ? ? 0.1 a output noise voltage v no v in = v out + 1 v, i out = 10 ma, 10 hz < = f < = 100 khz, c noise = 0.01 f, ta = 25c ? 30 ? v rms temperature coefficient t cvo ? 40c < = t opr < = 85c ? 100 ? ppm/c input voltage v in ? 2.4 ? 15 v ripple rejection r.r. v in = v out + 1 v, i out = 10 ma, c noise = 0.01 f, f = 1 khz, v ripple = 500 mv p-p , ta = 25c ? 70 ? db control voltage (on) v ct (on) ? 1.5 ? v in v control voltage (off) v ct (off) ? ? ? 0.4 v control current (on) i ct (on) v ct = 1.5 v ? 3 10 a control current (off) i ct (off) v ct = 0 v ? 0 0.1 a tar5s23~tar5s50 electrical characteristic (unless otherwise specified, v in = = = = v out + + + + 1 v, i out = = = = 50 ma, c in = = = = 1 f, c out = = = = 10 f, c noise = = = = 0.01 f, t j = = = = 25c) characteristics symbol test condition min typ. max unit output voltage v out please refer to the output voltage accuracy table. line regulation reg �k line v out + 1 v < = v in < = 15 v, i out = 1 ma ? 3 15 mv load regulation reg �k load 1 ma < = i out < = 150 ma ? 25 75 mv i b1 i out = 0 ma ? 170 ? quiescent current i b2 i out = 50 ma ? 550 850 a stand-by current i b (off) v ct = 0 v ? ? 0.1 a output noise voltage v no v in = v out + 1 v, i out = 10 ma, 10 hz < = f < = 100 khz, c noise = 0.01 f, ta = 25c ? 30 ? v rms dropout volatge v in ? v out i out = 50 ma ? 130 200 mv temperature coefficient t cvo ? 40c < = t opr < = 85c ? 100 ? ppm/c input voltage v in ? v out + 0.2 v ? 15 v ripple rejection r.r. v in = v out + 1 v, i out = 10 ma, c noise = 0.01 f, f = 1 khz, v ripple = 500 mv p-p , ta = 25c ? 70 ? db control voltage (on) v ct (on) ? 1.5 ? v in v control voltage (off) v ct (off) ? ? ? 0.4 v control current (on) i ct (on) v ct = 1.5 v ? 3 10 a control current (off) i ct (off) v ct = 0 v ? 0 0.1 a
TAR5S15~tar5s50 2000-10-30 4/22 output voltage accuracy ( v in = = = = v out + + + + 1 v, i out = = = = 50 ma, c in = = = = 1 f, c out = = = = 10 f, c noise = = = = 0.01 f, t j = = = = 25c) product no. symbol min typ. max unit TAR5S15 1.44 1.5 1.56 tar5s18 1.74 1.8 1.86 tar5s20 1.94 2.0 2.06 tar5s21 2.04 2.1 2.16 tar5s22 2.14 2.2 2.26 tar5s23 2.24 2.3 2.36 tar5s25 2.43 2.5 2.57 tar5s27 2.63 2.7 2.77 tar5s28 2.73 2.8 2.87 tar5s29 2.83 2.9 2.97 tar5s30 2.92 3.0 3.08 tar5s31 3.02 3.1 3.18 tar5s32 3.12 3.2 3.28 tar5s33 3.21 3.3 3.39 tar5s35 3.41 3.5 3.59 tar5s45 4.38 4.5 4.62 tar5s48 4.68 4.8 4.92 tar5s50 v out 4.87 5.0 5.13 v
TAR5S15~tar5s50 2000-10-30 5/22 application note 1. recommended application circuit the figure above shows the recommended configuration for using a point regulator. insert a capacitor for stable input/output operation. if the control function is not to be used, toshiba recommend that the control pin (pin 1) be connected to the v cc pin. 2. power dissipation the power dissipation for board-mounted tar5sxx series devices (rated at 380 mw) is measured using a board whose size and pattern are as shown below. when incorporating a device belonging to this series into your design, derate the power dissipation as far as possible by reducing the levels of parameters such as input voltage, output current and ambient temperature. toshiba recommend that these devices should typically be derated to 70%~80% of their absolute maximum power dissipation value. thermal resistance evaluation board circuit board material: glass epoxy, circuit board dimension:30 mm 30 mm, copper foil pad area: 50 mm 2 (t = 0.8 mm) c out c in c noise v in v out control gnd noise v in 5 noise 4 1 3 gnd 2 v out control 0.01 f 1 f 10 f control level operation high on low off
TAR5S15~tar5s50 2000-10-30 6/22 3. ripple rejection the devices of the tar5sxx series feature a circuit with an excellent ripple rejection characteristic. because the circuit also features an excellent output fluctuation characteristic for sudden supply voltage drops, the circuit is ideal for use in the rf blocks incorporated in all mobile telephones. 4. noise pin tar5sxx series devices incorporate a noise pin to reduce output noise voltage. inserting a capacitor between the noise pin and gnd reduces output noise. to ensure stable operation, insert a capacitor of 0.0047 f or more between the noise pin and gnd. the output voltage rise time varies according to the capacitance of the capacitor connected to the noise pin. ripple rejection ? f tar5s28 input transient response frequency f (hz) time t (ms) ripple rejection (db) 0 10 100 1 k 10 k 100 k 300 k 10 20 30 40 50 60 70 80 10 f 2.2 f 1 f v in = 4.0 v, c noise = 0.01 f, c in = 1 f, v ripple = 500 mv p ? p , i out = 10 ma, ta = 25 c c noise ? v n turn on waveform noise capacitance c noise (f) time t (ms) control voltage v ct (on) (v) output noise voltage v n ( v) 0 10 20 30 40 50 60 0.001 0.01 1.0 tar5s50 0.1 tar5s30 TAR5S15 c in = 1 f, c out = 10 f, i out = 10 ma, ta = 25 c output voltage v out (v) 0 1 4 5 8 10 input voltage 2.8 v 2 3 6 7 9 output voltage 3.1 v 3.4 v ta = 25 c, c in = 1 f, c out = 10 f, c noise = 0.01 f, v in : 3.4 v 3.1 v, i out = 50 ma 40 10 20 0 1 2 3 1 2 ? 10 0 90 30 0 60 50 80 70 output voltage waveform control voltage waveform c noise = 0.01 f 1 f 0.33 f 0.1 f c in = 1 f, c out = 10 f, i out = 50 ma, ta = 25 c
TAR5S15~tar5s50 2000-10-30 7/22 5. example of characteristics when ceramic capacitor is used shown below is the stable operation area, where the output voltage does not oscillate, evaluated using a toshiba evaluation circuit. the equivalent series resistance (esr) of the output capacitor and output current determines this area. tar5sxx series devices operate stably even when a ceramic capacitor is used as the output capacitor. if a ceramic capacitor is used as the output capacitor and the ripple frequency is 30 khz or more, the ripple rejection differs from that when a tantalum capacitor is used. this is shown below. toshiba recommend that users check that devices operate stably under the intended conditions of use. examples of safe operating area characteristics evaluation circuit for stable operating area ripple rejection characteristic (f = = = = 10 khz~300 khz) (TAR5S15) stable operating area output current i out (ma) (tar5s50) stable operating area (tar5s28) stable operating area output current i out (ma) output current i out (ma) equivalent series resistance esr ( ? ) equivalent series resistance esr ( ? ) equivalent series resistance esr ( ? ) ripple rejection (db) (tar5s30) ripple rejection ? f frequency f (hz) tar5s ** gnd c in ceramic v in = v out + 1 v control c noise = 0.01 f r out esr c out ceramic capacitors used for evaluation made by murata c in : grm40b105k c out : grm40b105k/grm40b106k 30 0 10 20 40 70 50 60 ceramic 2.2 f 10 k 300 k 100 k ceramic 10 f tantalum10 f tantalum 2.2 f tantalum 1 f ceramic 1 f @v in = 4.0 v, c noise = 0.01 f, c in = 1 f, v ripple = 500 mv p-p , i out = 10 ma, ta = 25 c 1000 k 80 40 0.02 0.1 1 10 100 0 20 150 60 120 100 140 @v in = 2.5 v, c noise = 0.01 f, c in = 1 f, c out = 1 f~10 f, ta = 25 c stable operating area 80 40 0.02 0.1 1 10 100 0 20 150 60 120 100 140 @v in = 6.0 v, c noise = 0.01 f, c in = 1 f, c out = 1 f~10 f, ta = 25 c stable operating area 80 40 0.02 0.1 1 10 100 0 20 150 60 120 100 140 @v in = 3.8 v, c noise = 0.01 f, c in = 1 f, c out = 1 f~10 f, ta = 25 c stable operating area
TAR5S15~tar5s50 2000-10-30 8/22 output voltage v out (v) output voltage v out (v) output current i out (ma) (TAR5S15) i out ? v out output voltage v out (v) output current i out (ma) (tar5s18) i out ? v out output voltage v out (v) output current i out (ma) (tar5s20) i out ? v out output voltage v out (v) output current i out (ma) (tar5s21) i out ? v out output current i out (ma) (tar5s22) i out ? v out output current i out (ma) (tar5s23) i out ? v out output voltage v out (v) 1.4 1.5 1.6 v in = 2.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 1.7 1.8 1.9 v in = 2.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 1.9 2.0 2.1 v in = 3.0 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 2.0 2.1 2.2 v in = 3.1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 2.1 2.2 2.3 v in = 3.2 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 2.2 2.3 v in = 3.3 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25
TAR5S15~tar5s50 2000-10-30 9/22 output current i out (ma) (tar5s27) i out ? v out output voltage v out (v) v in = 3.7 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 2.6 2.7 2.8 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s30) i out ? v out output voltage v out (v) v in = 3.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 2.7 2.8 2.9 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s25) i out ? v out output voltage v out (v) output current i out (ma) (tar5s31) i out ? v out output voltage v out (v) v in = 3.9 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 2.8 2.9 3 0 50 100 150 ta = 85 c 25 ? 40 2.4 2.5 2.6 v in = 2.6 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25 output current i out (ma) (tar5s28) i out ? v out output voltage v out (v) output current i out (ma) (tar5s29) i out ? v out output voltage v out (v) v in = 4.0 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 2.9 3.0 3.1 0 50 100 150 ta = 85 c 25 ? 40 3.0 3.1 3.2 v in = 4.1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25
TAR5S15~tar5s50 2000-10-30 10/22 output current i out (ma) (tar5s32) i out ? v out output voltage v out (v) output current i out (ma) (tar5s33) i out ? v out output voltage v out (v) v in = 4.3 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 3.2 3.3 3.4 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s45) i out ? v out output voltage v out (v) v in = 5.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 4.4 4.5 4.6 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s50) i out ? v out output voltage v out (v) v in = 6.0 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 4.9 5.0 5.1 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s35) i out ? v out output voltage v out (v) v in = 4.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 3.4 3.5 3.6 0 50 100 150 ta = 85 c 25 ? 40 output current i out (ma) (tar5s48) i out ? v out output voltage �y v out (v) v in = 5.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 4.7 4.8 4.9 0 50 100 150 ta = 85 c 25 ? 40 3.1 3.2 3.3 v in = 4.2 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 50 100 150 ta = 85 c ? 40 25
TAR5S15~tar5s50 2000-10-30 11/22 bias current i b (ma) bias current i b (ma) input voltage v in (v) (TAR5S15) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s18) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s20) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s21) i b ? v in input voltage v in (v) (tar5s22) i b ? v in input voltage v in (v) (tar5s23) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1
TAR5S15~tar5s50 2000-10-30 12/22 input voltage v in (v) (tar5s27) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 input voltage v in (v) (tar5s30) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 input voltage v in (v) (tar5s25) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s31) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s28) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 input voltage v in (v) (tar5s29) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1
TAR5S15~tar5s50 2000-10-30 13/22 input voltage v in (v) (tar5s32) i b ? v in bias current i b (ma) input voltage v in (v) (tar5s33) i b ? v in bias current i b (ma) 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms input voltage v in (v) (tar5s45) i b ? v in bias current i b (ma) 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms input voltage v in (v) (tar5s50) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms input voltage v in (v) (tar5s35) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1 input voltage v in (v) (tar5s48) i b ? v in bias current i b (ma) c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 5 10 0 5 10 15 i out = 150 ma 100 50 1
TAR5S15~tar5s50 2000-10-30 14/22 output voltage v out (v) output voltage v out (v) input voltage v in (v) (TAR5S15) v out ? v in output voltage v out (v) input voltage v in (v) (tar5s18) v out ? v in output voltage v out (v) input voltage v in (v) (tar5s20) v out ? v in output voltage v out (v) input voltage v in (v) (tar5s21) v out ? v in input voltage v in (v) (tar5s22) v out ? v in input voltage v in (v) (tar5s23) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms
TAR5S15~tar5s50 2000-10-30 15/22 input voltage v in (v) (tar5s27) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s30) v out ? v in output voltage v out (v) input voltage v in (v) (tar5s25) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s31) v out ? v in output voltage v out (v) input voltage v in (v) (tar5s28) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s29) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms
TAR5S15~tar5s50 2000-10-30 16/22 input voltage v in (v) (tar5s33) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s32) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s45) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s50) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s48) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms input voltage v in (v) (tar5s35) v out ? v in output voltage v out (v) 0 5 10 15 0 3 6 1 2 4 5 i out = 1 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms
TAR5S15~tar5s50 2000-10-30 17/22 output voltage v out (v) output voltage v out (v) ambient temperature ta ( c) (TAR5S15) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s18) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s20) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s21) v out ? ta ambient temperature ta ( c) (tar5s22) v out ? ta ambient temperature ta ( c) (tar5s23) v out ? ta output voltage v out (v) ? 50 1.4 ? 25 0 25 100 75 50 1.45 1.5 1.55 1.6 v in = 2.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 1.7 ? 25 0 25 100 75 50 1.75 1.8 1.85 1.9 v in = 2.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 1.9 ? 25 0 25 100 75 50 1.95 2.0 2.05 2.1 v in = 3.0 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 2.0 ? 25 0 25 100 75 50 2.05 2.1 2.15 2.2 v in = 3.1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 2.1 ? 25 0 25 100 75 50 2.15 2.2 2.25 2.3 v in = 3.2 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 2.2 ? 25 0 25 100 75 50 2.25 2.3 2.35 2.4 v in = 3.3 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150
TAR5S15~tar5s50 2000-10-30 18/22 ambient temperature ta ( c) (tar5s25) v out ? ta output voltage v out (v) ? 50 2.4 ? 25 0 25 100 75 50 2.45 2.5 2.55 2.6 v in = 3.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ambient temperature ta ( c) (tar5s27) v out ? ta output voltage v out (v) ? 50 2.6 ? 25 0 25 100 75 50 2.65 2.7 2.75 2.8 v in = 3.7 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ambient temperature ta ( c) (tar5s30) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s31) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s28) v out ? ta output voltage v out (v) ? 50 2.7 ? 25 0 25 100 75 50 2.75 2.8 2.85 2.9 v in = 3.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 50 ma 100 150 ambient temperature ta ( c) (tar5s29) v out ? ta output voltage v out (v) ? 50 2.8 ? 25 0 25 100 75 50 2.85 2.9 2.95 3.0 v in = 3.9 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 2.9 ? 25 0 25 75 50 2.95 3.0 3.05 3.1 v in = 4 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 50 ma 100 100 150 ? 50 3.0 ? 25 0 25 100 75 50 3.05 3.1 3.15 3.2 v in = 4.1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150
TAR5S15~tar5s50 2000-10-30 19/22 ambient temperature ta ( c) (tar5s32) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s33) v out ? ta output voltage v out (v) ? 50 3.2 ? 25 0 25 75 50 3.25 3.3 3.35 3.4 v in = 4.3 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 100 150 ambient temperature ta ( c) (tar5s45) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s50) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s35) v out ? ta output voltage v out (v) ambient temperature ta ( c) (tar5s48) v out ? ta output voltage v out (v) ? 50 4.4 ? 25 0 25 100 75 50 4.45 4.5 4.55 4.6 v in = 5.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 3.4 ? 25 0 25 100 75 50 3.45 3.5 3.55 3.6 v in = 4.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150 ? 50 4.9 ? 25 0 25 100 75 50 4.95 5 5.05 5.1 v in = 6 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 50 ma 100 150 ? 50 4.7 ? 25 0 25 100 75 50 4.75 4.8 4.85 4.9 v in = 5.8 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 50 ma 100 150 ? 50 3.1 ? 25 0 25 100 75 50 3.15 3.2 3.25 3.3 v in = 4.2 v, c in = 1 f, c out = 10 f, c noise = 0.01 f, pulse width = 1 ms i out = 50 ma 100 150
TAR5S15~tar5s50 2000-10-30 20/22 ? 50 ? 25 0 25 100 75 50 0 0.1 0.2 0.3 0.4 0.5 0.6 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 150 ma 100 50 10 1 ambient temperature ta ( c) i b ? ta bias current i b (ma) ambient temperature ta ( c) (tar5s23~tar5s50) v in - v out ? ta dropout voltage v in - v out (v) output current i out (ma) (tar5s23~tar5s50) v in - v out ? i out dropout voltage v in - v out (v) output current i out (ma) i b ? i out bias current i b (ma) time t (ms) turn on waveform output voltage vout (v) time t (ms) turn off waveform output voltage v out (v) ? 50 ? 25 0 25 100 75 50 0 0.5 1 1.5 2 2.5 3 v in = v out + 1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms i out = 150 ma 100 50 10 1 0 50 100 150 ta = 25 c 85 ? 40 0 0.1 0.2 0.3 0.4 0.5 c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms v in = v out + 1 v, v ct (on) = 1.5 0 v, c in = 1 f, c out = 10 f, c noise = 0.01 f 0 1 control voltage waveform output voltage waveform 2 3 0 1 0 1 2 3 2 3 0 1 0 1 2 3 v in = v out + 1 v, v ct (on) = 0 1.5 v, c in = 1 f, c out = 10 f, c noise = 0.01 f 0 1 ta = 25 c 85 ? 40 control voltage waveform output voltage waveform control voltage v ct (on) (v) control voltage v ct (on) (v) v in = v out + 1 v, c in = 1 f, c out = 10 f, c noise = 0.01 f pulse width = 1 ms 0 0.5 1.0 1.5 2.0 2.5 0 50 100 150 ta = 25 c 85 ? 40
TAR5S15~tar5s50 2000-10-30 21/22 ambient temperature ta ( c) p d ? ta power dissipation p d (mw) ? 40 0 0 40 120 80 100 200 300 400 �?�? circuit board material: glass epoxy, circuit board dimention: 30 mm 30 mm, pad area: 50 mm 2 (t = 0.8 mm) �?�? unit �? �? frequency f (hz) v n ? f output noise voltage v n ( v/ hz = v out + 1 v, i out = 10 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, 10 hz < f < 100 khz, ta = 25 c 10 1 0.1 0.01 0.001 10 100 1 k 10 k 100 k frequency f (hz) ripple rejection ? f ripple rejection (db) 0 10 20 60 70 80 30 40 50 10 100 1 k 10 k 100 k 1000 k v in = v out + 1 v, i out = 10 ma, c in = 1 f, c out = 10 f, c noise = 0.01 f, v ripple = 500 mv p-p , ta = 25 c TAR5S15 (1.5 v) tar5s30 (3.0 v) tar5s50 (5.0 v) tar5s45 (4.5 v) tar5s35 (3.5 v) tar5s25 (2.5 v)
TAR5S15~tar5s50 2000-10-30 22/22 �? package dimensions weight: 0.014 g (typ.)
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