NCP ma, Tri-Mode, LDO Linear Voltage Regulator

Transcription

1 3 ma, Tri-Mode, LDO Linear Voltage Regulator The NCP4589 is a CMOS 3 ma LDO which switches to a low power mode under light current loads. The device automatically switches back to a fast response mode as the output load increases above 3 ma (typ.). The device can be placed in permanent fast mode through a mode select pin. The family is available in a variety of packages: SC 7, SOT23 and a small, ultra thin 1.2 x 1.2 x.4 mm XDFN. MARKING DIAGRAMS Features Operating Input Voltage Range: 1.4 V to 5.25 V Output Voltage Range:.8 to 4. V (available in.1 V steps) Supply Current: Low Power Mode 1. A at V OUT < 1.85 V Fast Mode 55 A Standby Mode.1 A Dropout Voltage: 23 mv Typ. at I OUT = 3 ma, V OUT = 2.8 V ±1% Output Voltage Accuracy (V OUT > 2 V, T J = 25 C) High PSRR: 7 db at 1 khz (Fast response mode) Line Regulation.2%/V Typ. Current Fold Back Protection Stable with Ceramic Capacitors Available in 1.2x1.2 XDFN, SC 7 and SOT23 Package These are Pb free Devices SC 7 CASE 419A XDFN6 CASE 711AA SOT 23 5 CASE XXX XMM XX MM XXXMM Typical Applications Battery Powered Equipments Portable Communication Equipments Cameras, Image Sensors and Camcorders VIN C1 1 VIN CE AE NCP4589 GND VOUT C2 1 VOUT XXXX MM = Specific Device Code = Date Code ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 27 of this data sheet. Figure 1. Typical Application Schematic Semiconductor Components Industries, LLC, 212 February, 212 Rev. 1 1 Publication Order Number: NCP4589/D

2 AE AE Vin Vout Vin Vout Vref Vref CE Current Limit CE Current Limit GND GND NCP4589Hxxxx Figure 2. Simplified Schematic Block Diagram NCP4589Dxxxx PIN FUNCTION DESCRIPTION Pin No. XDFN Pin No. SC 7 Pin No. SOT23 Pin Name Description VIN Input pin GND Ground CE Chip enable pin VOUT Output pin AE Auto Eco Pin 5 NC No connection ABSOLUTE MAXIMUM RATINGS Rating Symbol Value Unit Input Voltage (Note 1) V IN 6. V Output Voltage VOUT.3 to VIN +.3 V Chip Enable Input VCE.3 to 6. V Auto Eco Input V AE.3 to 6. V Output Current I OUT 4 ma Power Dissipation XDFN P D 4 mw Power Dissipation SC7 38 Power Dissipation SOT23 42 Junction Temperature T J 4 to 15 C Storage Temperature T STG 55 to 125 C Operation Temperature T A 4 to 85 C ESD Capability, Human Body Model (Note 2) ESD HBM 2 V ESD Capability, Machine Model (Note 2) ESD MM 2 V Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability. 1. Refer to ELECTRICAL CHARACTERISTIS and APPLICATION INFORMATION for Safe Operating Area. 2. This device series incorporates ESD protection and is tested by the following methods: ESD Human Body Model tested per AEC Q1 2 (EIA/JESD22 A114) ESD Machine Model tested per AEC Q1 3 (EIA/JESD22 A115) Latchup Current Maximum Rating tested per JEDEC standard: JESD78. 2

3 THERMAL CHARACTERISTICS Rating Symbol Value Unit Thermal Characteristics, XDFN Thermal Resistance, Junction to Air Thermal Characteristics, SOT23 Thermal Resistance, Junction to Air Thermal Characteristics, SC 7 Thermal Resistance, Junction to Air R JA 25 C/W R JA 238 C/W R JA 263 C/W ELECTRICAL CHARACTERISTICS 4 C T A 85 C; V IN = V OUT(NOM) + 1 V; I OUT = 1 ma; C IN = C OUT = 1 F; unless otherwise noted. Typical values are at T A = +25 C. Parameter Test Conditions Symbol Min Typ Max Unit Operating Input Voltage (Note NO TAG) VIN V Output Voltage (Fast Mode) Output Voltage Temp. Coefficient TA = +25 C, I OUT = 5 ma 4 C TA 85 C, I OUT = 5 ma V OUT > 2 V VOUT x.99 x1.1 V V OUT 2 V 2 2 mv V OUT > 2 V x.9 x1.15 V V OUT 2 V 5 3 mv T A = 4 to 85 C ±5 ppm/ C Line Regulation V IN = VOUT +.5 V to 5 V V IN 1.4 V I OUT = 1 ma, (Low Power Mode) I OUT = 1 ma, (Fast Mode) Line Reg.5 %/V.2.2 Load Regulation IOUT = 1 ma to 1 ma V OUT > 2. V Line Reg % V OUT 2. V 2 2 mv IOUT = 1 ma to 3 ma 35 8 mv Dropout Voltage I OUT = 3 ma.8 V V OUT <.9 V VDO V.9 V V OUT < 1. V V V OUT < 1.5 V V V OUT < 2.6 V V V OUT < 4. V Output Current IOUT 3 ma Short Current Limit V OUT = V I SC 5 ma Quiescent Current IOUT = ma, Low Power Mode (Note 3) V OUT 1.85 V IQ A V OUT > 1.85 V Supply Current I OUT = 1 ma, Fast Mode I GND 55 A Standby Current V CE = V, T A = 25 C ISTB.1 1 A Fast Mode Switch Over Current I OUT = light to heavy load I OUTH 8. ma Low Power Switch Over Current I OUT = heavy to light load I OUTL ma CE Pin Threshold Voltage CE Input Voltage H VCEH 1. V CE Input Voltage L VCEL.4 CE Pull Down Current ICEPD.1 A AE Pin Threshold Voltage AE Input Voltage H VAEH 1. V AE Input Voltage L VAEL.4 3. The value of supply current is excluding the Pull down constant current of CE and AE Pin 3

4 ELECTRICAL CHARACTERISTICS 4 C T A 85 C; V IN = V OUT(NOM) + 1 V; I OUT = 1 ma; C IN = C OUT = 1 F; unless otherwise noted. Typical values are at T A = +25 C. Parameter Test Conditions Symbol AE Pull Down Current IAEPD.1 A Power Supply Rejection Ratio Output Noise Voltage VIN = V OUT + 1 V or 2.2 V whichever is higher, V IN =.2 V pk pk, IOUT = 3 ma, f = 1 khz, Fast Mode V OUT = 1. V, IOUT = 3 ma, f = 1 Hz to 1 khz Min Typ Max Unit PSRR 7 db VN 9 V rms Low Output N channel Tr. On Resistance V IN = 4 V, V CE = V R LOW 5 3. The value of supply current is excluding the Pull down constant current of CE and AE Pin 4

5 V IN = 1.8 V V 1.4 V 2.8 V 3.8 V V IN = 1.6 V 5.25 V 3.8 V 2.8 V 1.8 V I OUT, OUTPUT CURRENT (ma) I OUT, OUTPUT CURRENT (ma) Figure 3. Output Voltage vs. Output Current Figure 4. Output Voltage vs. Output Current 1. V Version (T J = 25 C) 1.2 V Version (T J = 25 C) V 5.25 V V IN = 2.8 V I OUT, OUTPUT CURRENT (ma) Figure 5. Output Voltage vs. Output Current 1.8 V Version (T J = 25 C) V 5.25 V V IN = 3.8 V I OUT, OUTPUT CURRENT (ma) Figure 6. Output Voltage vs. Output Current 3.3 V Version (T J = 25 C) T J = 85 C.4 T J = 85 C V DO (V) C 4 C V DO (V) C 4 C I OUT, OUTPUT CURRENT (ma) Figure 7. Dropout Voltage vs. Output Current 1. V Version I OUT, OUTPUT CURRENT (ma) Figure 8. Dropout Voltage vs. Output Current 1.2 V Version 5

6 .4.3 V DO (V) C T J = 85 C 4 C V DO (V) C T J = 85 C 4 C I OUT, OUTPUT CURRENT (ma) I OUT, OUTPUT CURRENT (ma) Figure 9. Dropout Voltage vs. Output Current 1.8 V Version Figure 1. Dropout Voltage vs. Output Current 3.3 V Version ma 3 ma ma I OUT = 5 ma ma I OUT = 5 ma V IN, INPUT VOLTAGE (V) Figure 11. Output Voltage vs. Input Voltage, 1. V Version V IN, INPUT VOLTAGE (V) Figure 12. Output Voltage vs. Input Voltage, 1.2 V Version ma 3 ma ma I OUT = 5 ma ma I OUT = 5 ma V IN, INPUT VOLTAGE (V) Figure 13. Output Voltage vs. Input Voltage, 1.8 V Version V IN, INPUT VOLTAGE (V) Figure 14. Output Voltage vs. Input Voltage, 3.3 V Version 6

7 1.4 V IN = 2. V 1.24 V IN = 2.2 V T J, JUNCTION TEMPERATURE ( C) Figure 15. Output Voltage vs. Temperature, 1. V Version T J, JUNCTION TEMPERATURE ( C) Figure 16. Output Voltage vs. Temperature, 1.2 V Version V IN = 2.8 V T J, JUNCTION TEMPERATURE ( C) Figure 17. Output Voltage vs. Temperature, 1.8 V Version V IN = 4.3 V T J, JUNCTION TEMPERATURE ( C) Figure 18. Supply Current vs. Input Voltage, 3.3 V Version I OUT = 1 ma 6 5 I OUT = 1 ma I GND ( A) I GND ( A) I OUT = ma V IN, INPUT VOLTAGE (V) Figure 19. Supply Current vs. Input Voltage, 1. V Version 1 I OUT = ma V IN, INPUT VOLTAGE (V) Figure 2. Supply Current vs. Input Voltage, 1.2 V Version 7

8 7 6 I OUT = 1 ma I GND ( A) 4 3 I GND ( A) 4 3 I OUT = 1 ma 2 1 I OUT = ma V IN, INPUT VOLTAGE (V) Figure 21. Supply Current vs. Input Voltage, 1.8 V Version 2 1 I OUT = ma V IN, INPUT VOLTAGE (V) Figure 22. Supply Current vs. Input Voltage, 3.3 V Version 12 1 V IN = 2. V AE = V 12 1 V IN = 2.2 V AE = V 8 8 I GND ( A) Heavy to Light Load Light to Heavy Load I GND ( A) Heavy to Light Load Light to Heavy Load I OUT, OUTPUT CURRENT (ma) I OUT, OUTPUT CURRENT (ma) Figure 23. Supply Current vs. Output Current, 1. V Version Figure 24. Supply Current vs. Output Current, 1.2 V Version 12 1 V IN = 2.8 V AE = V 12 1 V IN = 4.3 V AE = V I GND ( A) 4 2 Heavy to Light Load Light to Heavy Load I GND ( A) 4 2 Heavy to Light Load Light to Heavy Load I OUT, OUTPUT CURRENT (ma) I OUT, OUTPUT CURRENT (ma) Figure 25. Supply Current vs. Output Current, 1.8 V Version Figure 26. Supply Current vs. Output Current, 3.3 V Version 8

9 V IN = 2. V AE = V V IN = 2.2 V AE = V I IN ( A) 1.5 I IN ( A) T J, JUNCTION TEMPERATURE ( C) Figure 27. Supply Current vs. Temperature, 1. V Version T J, JUNCTION TEMPERATURE ( C) Figure 28. Supply Current vs. Temperature, 1.2 V Version V IN = 2.8 V AE = V V IN = 4.3 V AE = V I IN ( A) 1.5 I IN ( A) T J, JUNCTION TEMPERATURE ( C) Figure 29. Supply Current vs. Temperature, 1.8 V Version T J, JUNCTION TEMPERATURE ( C) Figure 3. Supply Current vs. Temperature, 3.3 V Version 55 5 V IN = 2. V AE = 2. V 55 5 V IN = 2.2 V AE = 2.2 V I IN ( A) 4 I IN ( A) T J, JUNCTION TEMPERATURE ( C) Figure 31. Supply Current vs. Temperature, 1. V Version T J, JUNCTION TEMPERATURE ( C) Figure 32. Supply Current vs. Temperature, 1.2 V Version 9

10 55 5 V IN = 2.8 V AE = 2.8 V 55 5 V IN = 4.3 V AE = 4.3 V I IN ( A) 4 I IN ( A) T J, JUNCTION TEMPERATURE ( C) Figure 33. Supply Current vs. Temperature, 1.8 V Version T J, JUNCTION TEMPERATURE ( C) Figure 34. Supply Current vs. Temperature, 3.3 V Version PSRR (db) I OUT = 1 ma AE = Low 5 ma I OUT = 1 ma AE = High 1 ma 3 ma FREQUENCY (khz) Figure 35. PSRR, 1. V Version, V IN = 2.2 V PSRR (db) I OUT = 1 ma AE = Low 5 ma I OUT = 1 ma AE = High 3 ma 1 ma FREQUENCY (khz) Figure 36. PSRR, 1.2 V Version, V IN = 2.2 V PSRR (db) I OUT = 1 ma AE = Low 3 ma I OUT = 1 ma AE = High 5 ma 1 ma FREQUENCY (khz) PSRR (db) ma I OUT = 1 ma AE = Low 1 ma I OUT = 1 ma AE = High 3 ma FREQUENCY (khz) Figure 37. PSRR, 1.8 V Version, V IN = 3.8 V Figure 38. PSRR, 3.3 V Version, V IN = 4.3 V 1

11 V N ( V rms / Hz) V N ( V rms / Hz) FREQUENCY (khz) Figure 39. Output Voltage Noise, 1. V Version, V IN = 2. V, I OUT = 3 ma FREQUENCY (khz) Figure 41. Output Voltage Noise, 1.8 V Version, V IN = 2.8 V, I OUT = 3 ma V N ( V rms / Hz) V N ( V rms / Hz) FREQUENCY (khz) Figure 4. Output Voltage Noise, 1.2 V Version, V IN = 2.2 V, I OUT = 3 ma FREQUENCY (khz) Figure 42. Output Voltage Noise, 3.3 V Version, V IN = 4.3 V, I OUT = 3 ma t, TIME (ms) Figure 43. Line Transients, 1. V Version, t R = t F = 5 s, I OUT = 1 ma, AE = V V IN (V) 11

12 Figure 44. Line Transients, 1.2 V Version, t R = t F = 5 s, I OUT = 1 ma, AE = V V IN (V) Figure 45. Line Transients, 1.8 V Version, t R = t F = 5 s, I OUT = 1 ma, AE = V V IN (V) Figure 46. Line Transients, 3.3 V Version, t R = t F = 5 s, I OUT = 1 ma, AE = V V IN (V) 12

13 Figure 47. Line Transients, 1. V Version, t R = t F = 5 s, I OUT = 3 ma, AE = V IN V V IN (V) Figure 48. Line Transients, 1.2 V Version, t R = t F = 5 s, I OUT = 3 ma, AE = V IN V V IN (V) Figure 49. Line Transients, 1.8 V Version, t R = t F = 5 s, I OUT = 3 ma, AE = V IN V V IN (V) 13

14 Figure 5. Line Transients, 3.3 V Version, t R = t F = 5 s, I OUT = 3 ma, AE = V IN V V IN (V) Figure 51. Load Transients, 1. V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2. V, AE = V Figure 52. Load Transients, 1. V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2. V, AE = V IN V

15 Figure 53. Load Transients, 1.2 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2.2 V, AE = V Figure 54. Load Transients, 1.2 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2.2 V, AE = V IN V Figure 55. Load Transients, 1.8 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2.8 V, AE = V

16 Figure 56. Load Transients, 1.8 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 2.8 V, AE = V IN V Figure 57. Load Transients, 3.3 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 4.3 V, AE = V Figure 58. Load Transients, 3.3 V Version, I OUT = 1 5 ma, t R = t F =.5 s, V IN = 4.3 V, AE = V IN V

17 Figure 59. Load Transients, 1. V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2. V, AE = V Figure 6. Load Transients, 1. V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2. V, AE = V IN V Figure 61. Load Transients, 1.2 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2.2 V, AE = V

18 Figure 62. Load Transients, 1.2 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2.2 V, AE = V IN V Figure 63. Load Transients, 1.8 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2.8 V, AE = V Figure 64. Load Transients, 1.8 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 2.8 V, AE = V IN V

19 Figure 65. Load Transients, 3.3 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 4.3 V, AE = V Figure 66. Load Transients, 3.3 V Version, I OUT = 1 15 ma, t R = t F =.5 s, V IN = 4.3 V, AE = V IN V Figure 67. Load Transients, 1. V Version, I OUT = 5 1 ma, t R = t F =.5 s, V IN = 2. V, AE = V

20 Figure 68. Load Transients, 1.2 V Version, I OUT = 5 1 ma, t R = t F =.5 s, V IN = 2.2 V, AE = V IN V Figure 69. Load Transients, 1.8 V Version, I OUT = 5 1 ma, t R = t F =.5 s, V IN = 2.8 V, AE = V IN V Figure 7. Load Transients, 3.3 V Version, I OUT = 5 1 ma, t R = t F =.5 s, V IN = 4.3 V, AE = V IN V

21 V AE (V) t, TIME (ms) Figure 71. AE Switch Transients, 1. V Version, V IN = 2. V, I OUT = 1 ma V AE (V) t, TIME (ms) Figure 72. AE Switch Transients, 1. V Version, V IN = 2. V, I OUT = 1 ma V AE (V) t, TIME (ms) Figure 73. AE Switch Transients, 1.2 V Version, V IN = 2.2 V, I OUT = 1 ma 21

22 t, TIME (ms) Figure 74. AE Switch Transients, 1.2 V Version, V IN = 2.2 V, I OUT = 1 ma V AE (V) t, TIME (ms) Figure. AE Switch Transients, 1.8 V Version, V IN = 2.8 V, I OUT = 1 ma V AE (V) t, TIME (ms) Figure 76. AE Switch Transients, 1.8 V Version, V IN = 2.8 V, I OUT = 1 ma V AE (V) 22

23 t, TIME (ms) Figure 77. AE Switch Transients, 3.3 V Version, V IN = 4.3 V, I OUT = 1 ma V AE (V) t, TIME (ms) Figure 78. AE Switch Transients, 3.3 V Version, V IN = 4.3 V, I OUT = 1 ma I OUT = 1 ma I OUT = 3 ma Chip Enable I OUT = 5 ma t ( s) Figure 79. Start up, 1. V Version, V IN = 2. V V AE (V) V CE (V) 23

24 Chip Enable I OUT = 1 ma I OUT = 5 ma I OUT = 3 ma t ( s) Figure 8. Start up, 1.2 V Version, V IN = 2.2 V V CE (V) Chip Enable I OUT = 5 ma I OUT = 1 ma I OUT = 3 ma t ( s) Figure 81. Start up, 1.8 V Version, V IN = 2.8 V V CE (V) Chip Enable I OUT = 1 ma I OUT = 5 ma I OUT = 3 ma t ( s) Figure 82. Start up, 3.3 V Version, V IN = 4.3 V V CE (V) 24

25 I OUT = 1 ma Chip Enable I OUT = 5 ma I OUT = 3 ma t ( s) Figure 83. Shutdown, 1. V Version D, V IN = 2. V V CE (V) Chip Enable I OUT = 5 ma I OUT = 3 ma I OUT = 1 ma t ( s) Figure 84. Shutdown, 1.2 V Version D, V IN = 2.2 V V CE (V) Chip Enable I OUT = 5 ma I OUT = 3 ma I OUT = 1 ma t ( s) Figure 85. Shutdown, 1.8 V Version D, V IN = 2.8 V V CE (V) 25

26 Chip Enable I OUT = 5 ma I OUT = 3 ma I OUT = 1 ma t ( s) Figure 86. Shutdown, 3.3 V Version D, V IN = 4.3 V V CE (V) APPLICATION INFORMATION A typical application circuit for NCP4589 series is shown in Figure 87. VIN C1 1 VIN CE AE NCP4589 GND VOUT C2 1 Figure 87. Typical Application Schematic VOUT Input Decoupling Capacitor (C1) A 1 F ceramic input decoupling capacitor should be connected as close as possible to the input and ground pin of the NCP4589. Higher values and lower ESR improves line transient response. Output Decoupling Capacitor (C2) A 1 F ceramic output decoupling capacitor is sufficient to achieve stable operation of the IC. If tantalum capacitor is used, and its ESR is high, the loop oscillation may result. If output capacitor is composed from few ceramic capacitors in parallel, the operation can be unstable. The capacitor should be connected as close as possible to the output and ground pin. Larger values and lower ESR improves dynamic parameters. Enable Operation The enable pin CE may be used for turning the regulator on and off. The regulator is switched on when CE pin voltage is above logic high level. The enable pin has internal pull down current source. If enable function is not needed connect CE pin to V IN. Current Limit This regulator includes fold-back type current limit circuit. This type of protection doesn t limit current up to current capability in normal operation, but when over current occurs, the output voltage and current decrease until the over current condition ends. Typical characteristics of this protection type can be observed in the Output Voltage versus Output Current graphs shown in the typical characteristics chapter of this datasheet. Output Discharger The D version includes a transistor between V OUT and GND that is used for faster discharging of the output capacitor. This function is activated when the IC goes into disable mode. Auto ECO and Fast Mode The NCP4589 has two operation modes that have impact on supply current and transient response at low output current. These two modes can be selected by AE pin. If AE pin is at low level Auto ECO mode is available. Please, see supply current vs. output current charts. Thermal As power across the IC increases, it might become necessary to provide some thermal relief. The maximum power dissipation supported by the device is dependent upon board design and layout. Mounting pad configuration on the PCB, the board material, and also the ambient temperature affect the rate of temperature rise for the part. That is to say, when the device has good thermal 26

27 conductivity through the PCB, the junction temperature will be relatively low with high power dissipation applications. capacitors C1 and C2 as close as possible to the IC, and make wiring as short as possible. PCB layout Make V IN and GND line sufficient. If their impedance is high, noise pickup or unstable operation may result. Connect ORDERING INFORMATION Device Nominal Output Voltage Description Marking Package Shipping NCP4589DSQ12T1G 1.2 V Auto discharge D12 SC 7 (Pb Free) NCP4589DSQ18T1G 1.8 V Auto discharge D18 SC 7 (Pb Free) NCP4589DSQ25T1G 2.5 V Auto discharge D25 SC 7 (Pb Free) NCP4589DSQ3T1G 3. V Auto discharge D3 SC 7 (Pb Free) NCP4589DSQ33T1G 3.3 V Auto discharge D33 SC 7 (Pb Free) NCP4589DSN12T1G 1.2 V Auto discharge P1E SOT 23 5 (Pb Free) NCP4589DSN18T1G 1.8 V Auto discharge P1L SOT 23 5 (Pb Free) NCP4589DSN25T1G 2.5 V Auto discharge P1T SOT 23 5 (Pb Free) NCP4589DSN3T1G 3. V Auto discharge P1Y SOT 23 5 (Pb Free) NCP4589DSN33T1G 3.3 V Auto discharge Q1B SOT 23 5 (Pb Free) NCP4589DMX12TCG 1.2 V Auto discharge 7E XDFN (Pb Free) NCP4589DMX18TCG 1.8 V Auto discharge 7L XDFN (Pb Free) NCP4589DMX28TCG 2.8 V Auto discharge 7W XDFN (Pb Free) NCP4589DMX3TCG 3. V Auto discharge 7Y XDFN (Pb Free) NCP4589DMX33TCG 3.3 V Auto discharge 8B XDFN (Pb Free) 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 3 / Tape & Reel 5 / Tape & Reel 5 / Tape & Reel 5 / Tape & Reel 5 / Tape & Reel 5 / Tape & Reel For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD811/D. NOTE: To order other package and voltage variants, please contact your ON Semiconductor sales representative. 27

28 PACKAGE DIMENSIONS SC 88A (SC 7 5/SOT 353) CASE 419A 2 ISSUE K S A G 5 4 B D 5 PL.2 (.8) M B M N NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, CONTROLLING DIMENSION: INCH A 1 OBSOLETE. NEW STANDARD 419A DIMENSIONS A AND B DO NOT INCLUDE MOLD FLASH, PROTRUSIONS, OR GATE BURRS. INCHES MILLIMETERS DIM MIN MAX MIN MAX A B C D G.26 BSC.65 BSC H J K N.8 REF.2 REF S C J H K 28

29 PACKAGE DIMENSIONS XDFN6 1.2x1.2,.4P CASE 711AA 1 ISSUE O 2X PIN ONE REFERENCE.5 C D ÍÍÍ ÍÍÍ 2X.5 C TOP VIEW.5 C A B E A NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, CONTROLLING DIMENSION: MILLIMETERS. 3. DIMENSION b APPLIES TO PLATED TERMINAL AND IS MEASURED BETWEEN.15 AND.25mm FROM TERMINAL TIPS. 4. COPLANARITY APPLIES TO ALL OF THE TERMINALS. MILLIMETERS DIM MIN MAX A A1..5 b C.2.3 D 1.2 BSC E 1.2 BSC e.4 BSC L NOTE 4.5 C SIDE VIEW A1 C SEATING PLANE RECOMMENDED MOUNTING FOOTPRINT* 6X 6X e PACKAGE OUTLINE 1 3 C 1.5 6X L 6 4 BOTTOM VIEW 6X b.5 M C A B NOTE 3.4 PITCH DIMENSIONS: MILLIMETERS *For additional information on our Pb Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. 29

30 PACKAGE DIMENSIONS SOT 23 5 LEAD CASE ISSUE A A E L1 e 5 1 D B E1 5X b.1 M C B S A S A2.5 S C C A1 RECOMMENDED SOLDERING FOOTPRINT* A L NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, CONTROLLING DIMENSIONS: MILLIMETERS. 3. DATUM C IS THE SEATING PLANE. MILLIMETERS DIM MIN MAX A A1..1 A b.3.5 c.1.25 D E E e.95 BSC L L X.85 5X PITCH DIMENSIONS: MILLIMETERS *For additional information on our Pb Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any 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, including 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 applications and actual performance may vary over time. All operating parameters, including Typicals must be validated for each customer application by customer s technical experts. 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 product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees 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 negligent 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 LITERATURE FULFILLMENT: Literature Distribution Center for ON Semiconductor P.O. Box 5163, Denver, Colorado 8217 USA Phone: or Toll Free USA/Canada Fax: or Toll Free USA/Canada orderlit@onsemi.com N. American Technical Support: Toll Free USA/Canada Europe, Middle East and Africa Technical Support: Phone: Japan Customer Focus Center Phone: ON Semiconductor Website: Order Literature: For additional information, please contact your local Sales Representative NCP4589/D