BIPOLAR ANALOG INTEGRATED CIRCUIT

Similar documents
BIPOLAR ANALOG INTEGRATED CIRCUIT

ZENER DIODES RD2.0S to RD150S

DATA SHEET ZENER DIODES 1 W DO-41 GLASS SEALED PACKAGE

Old Company Name in Catalogs and Other Documents

DATA SHEET ZENER DIODES 1.0 W PLANAR TYPE 2-PIN SMALL POWER MINI MOLD. Parameter Symbol Ratings Unit Remarks

Old Company Name in Catalogs and Other Documents

Old Company Name in Catalogs and Other Documents

MOS INTEGRATED CIRCUIT µ PD16510

Design Kit (for ANSOFT Designer TM / Nexxim TM ) User s Manual

ESD NOISE CLIPPING DIODE NNCD2.0DA to NNCD39DA

DATA SHEET. GaAs MMIC SP8T SWITCH FOR MOBILE COMMUNICATIONS

Monolithic Linear IC Separately-Excited Step-Down Switching Regulator (Variable Type)

LASER DIODE NX5322 Series

MOS INTEGRATED CIRCUIT

Packaging 1. Cathode 2. Anode V Zener operating resistance. 120 Reverse current IR VR = 1 V

PQ05RD08 Series/PQ3RD083/PQ6RD083

Low Power-Loss Voltage Regulators. (Ta=25 C) V V ma mw C C C C

INVERTER 84PW021. DATA SHEET DOD-PD-0743 (2nd edition) This DATA SHEET is updated document fromdod-pd-0364(1).

DZ L Silicon epitaxial planar type

200 ma 36 V Input Ultra Low Supply Current VR for Automotive Applications

20 Zener rise operating resistance RZK IZ = 0.5 ma. 60 Reverse current. 0.1 A Temperature coefficient of zener voltage *3 SZ IZ = 5 ma IR VR = 4 V

300 Zener rise operating resistance RZK IZ = 0.5 ma. 300 Reverse current A Temperature coefficient of zener voltage *3 SZ IZ = 2 ma

A79LXX BIPOLAR LINEAR REGULATOR THREE TERMINAL NEGATIVE VOLTAGE REGULATOR

LASER DIODE NX7304BG-CC

39.0MAX. (Ta=25 C) VIN to to (For 10s) PD1 PD2. Topr Tstg Tsol

DZ5X120D0R Silicon epitaxial planar type

DZ2S180C0L Silicon epitaxial planar type

1.0 V Zener voltage *1, *2 VZ IZ = 5 ma Zener operating resistance RZ IZ = 5 ma. 40 Zener rise operating resistance RZK IZ = 0.

DZ4J036K0R Silicon epitaxial planar type

Outline Drawings [mm] Connection diagram TFP. Item Symbols Conditions Ratings Units Repetitive peak reverse voltage VRRM 120 V

SOD-723 Electrostatic discharge *2 ESD ±30 kv Junction temperature Tj 150 C

MOS INTEGRATED CIRCUIT

Non-Isolated AC/DC Converter

Maintenance/ Discontinued

Dual back-to-back Zener diode

KA Terminal 1.5A Negative Adjustable Regulator. Features. Description. Internal Block Diagram. 3 Output.

MOS INTEGRATED CIRCUIT

MIC5282. General Description. Features. Applications. Typical Applications. 120V IN, 50mA, Ultra-Low I Q, High-PSRR Linear Regulator

INVERTER 104PW201. DATA SHEET DOD-PP-0047 (1st edition) This DATA SHEET is updated document from PRELIMINARY DATA SHEET DOD-PD-1322(1).

LM Terminal Positive Adjustable Regulator. Features. Description. Internal Block Diagram.

QUAD OPERATIONAL AMPLIFIER

1Z6.2~1Z390, 1Z6.8A~1Z30A

Maintenance/ Discontinued

R1524x Series. 200 ma 36 V Input Ultra Low Supply Current VR OUTLINE FEATURES APPLICATIONS. No. EA

MIC5281. Features. General Description. Applications. Typical Application. 120V IN, 25mA, Ultra-Low IQ, High-PSRR Linear Regulator

SiGe:C LOW NOISE AMPLIFIER FOR GPS

TOSHIBA Bipolar Linear Integrated Circuit Silicon Monolithic TA58LT00F. 150 ma Output Current and Tracking Regulator with ON/OFF Control Switch

SiGe:C LOW NOISE AMPLIFIER FOR GPS

pcs / reel (standard) Temperature coefficient of zener voltage *3 SZ IZ = 5 ma Terminal Capacitance Ct VR = 0 V, f = 1 MHz

SiGe:C LOW NOISE AMPLIFIER FOR GPS

Maintenance/ Discontinued

TOSHIBA Schottky Barrier Rectifier Schottky Barrier Type CMS05

LA Overview LA42152 is 15W 2-channel AF power amplifier intended for televisions.

TP805 OPTO INTERRUPTER

VCC -0.3 ~ 7 V. Maximum input voltage CP, CN, SHD, VOUT -0.3 ~ 7 V Power dissipation Pd 675 (*1) mw Operating temperature range

TOSHIBA Schottky Barrier Diode CMS16

SII Semiconductor Corporation, Rev.2.2_01

VP603. CRT Display Video Output Amplifier: High-Voltage, Wideband Amplification

1A Ultra Low Dropout Linear Regulator

Pd max2 * Mounted on a board. 800 mw Operating temperature Topr -40 to +85 C Storage temperature Tstg -55 to +150 C

TOSHIBA Zener Diode Silicon Epitaxial Type. CRY62 to CRZ39

A6150 LOW DROPOUT VOLTAGE REGULATOR 150mA CMOS LOW NOISE

Parameter Symbol Conditions Ratings Unit

CRY62~CRZ47 CRY62~CRZ47. Applications: Communication, Control and Measurement Equipment Constant Voltage Regulation Transient Suppressors

Low forward voltage Ultra small SMD plastic package Low capacitance Flat leads: excellent coplanarity and improved thermal behavior.

Low forward voltage Ultra small SMD plastic package Low capacitance Flat leads: excellent coplanarity and improved thermal behavior

LD A very low drop adjustable positive voltage regulator. Description. Features

TD62384APG,TD62384AFG TD62385APG,TD62385AFG

Problem Situations: Power Supply Does Not Start

MOS INTEGRATED CIRCUIT

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

PMEG1030EH; PMEG1030EJ

4-Channel 1-wire Dimming LED Driver with Ultra Low Dropout Current Source

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

PMEG3015EH; PMEG3015EJ

Parameter Symbol Min. TYP. MAX. Unit Operation Power Supply voltage This product is not designed for protection against radioactive rays.

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

Drop-In Replacement: CG2163X3. Part Number Order Number Package Marking Supplying Form G4X CAUTION

TD62M8600FG TD62M8600FG 8CH LOW SATURATION VOLTAGE SOURCE DRIVER FEATURES SCHEMATICS PIN CONNECTION (TOP VIEW)

TD62382AP,TD62382AF TD62382AP/AF 8CH LOW INPUT ACTIVE SINK DRIVER FEATURES PIN CONNECTION (TOP VIEW) SCHEMATICS (EACH DRIVER)

High Current Power Switch

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

LA4446. Car Stereo-Use 5.5W 2-Channel AF Power Amplifier. Package Dimensions

3.3 V, SILICON GERMANIUM MMIC WIDE BAND AMPLIFIER

Stepping motor driver

PMEG2010EH; PMEG2010EJ; PMEG2010ET

MAQ5281. Features. General Description. Applications. Typical Applications. 120V IN, 25mA, Ultra-Low I Q, High-PSRR Linear Regulator Automotive

RAD HARD ULTRA LOW DROPOUT ADJUSTABLE POSITIVE LINEAR REGULATOR

RP105x Series. Low Voltage 400 ma LDO Regulator OUTLINE FEATURES APPLICATIONS. *RP105Q (SC-88A) is the discontinued product as of April, 2018.

Bi-CMOS LSI PC and Server Fan Motor Driver

S-8880A Series ENERGY HARVESTING POWERED BY ULTRA-LOW POWER AND ULTRA-LOW VOLTAGE OPERATION BOOST CHARGE PUMP FOR STEP-UP DC-DC CONVERTER STARTUP

MAQ5282. Features. General Description. Applications. Typical Applications. 120V IN, 50mA, Ultra-Low I Q, High-PSRR Linear Regulator Automotive

XBP4SMAJ Series APPLICATIONS FEATURES PIN CONFIGRATION MARKING ABSOLUTE MAXIMUM RATINGS. 400W Transient Voltage Suppressor (TVS) 1/5.

2PB709ARL; 2PB709ASL

DATA SHEET. BGA2031/1 MMIC variable gain amplifier DISCRETE SEMICONDUCTORS. Product specification Supersedes data of 2000 Mar 02.

MOS INTEGRATED CIRCUIT

In data sheets and application notes which still contain NXP or Philips Semiconductors references, use the references to Nexperia, as shown below.

PNP 500 ma, 50 V resistor-equipped transistor; R1 = 2.2 kω, R2 = open

Since a 32-pin plastic SSOP package is used, the display unit size can be reduced.

Transcription:

DATA SHEET BIPOLAR ANALOG INTEGRATED CIRCUIT µpc29m33a,µpc29m5a THREE-TERMINAL LOW DROPOUT VOLTAGE REGULATOR DESCRIPTION The µpc29m33a, µpc29m5a of low dropout voltage three terminal positive regulators is constructed with PNP output transistor. The µpc29m33a, µpc29m5a feature the ability to source.5 A of output current with a low dropout voltage of typically.5 V. The power dissipation of the µpc29m33a, µpc29m5a can be drastically reduced compared with the conventional three terminal positive voltage regulators that is constructed with NPN output transistor. Also, this series corresponds to the low voltage output (3 V, 3.3 V) which is not in the conventional low dropout regulators ( µpc24ma series). FEATURES Output current in excess of.5 A Low dropout voltage VDIF =.5 V TYP. (at IO =.5 A) On-chip overcurrent and thermal protection circuit On-chip output transistor safe area protection circuit PIN CONFIGURATION (Marking Side) µpc29m33ahf, µ PC29M5AHF: MP-45G µ PC29M33AHB, µ PC29M5AHB: MP-3 µ PC29M33A, µ PC29M5AT: MP-3Z 4 1 2 3 1 2 1: INPUT 2: GND 3: OUTPUT 3 1: INPUT 2: GND 3: OUTPUT 4: GND (Fin) The information in this document is subject to change without notice. Before using this document, please confirm that this is the latest version. Not all devices/types available in every country. Please check with local NEC representative for availability and additional information. Document No. G15368EJ1VDS (1st edition) Date Published May 21 NS CP(K) Printed in Japan 21

BLOCK DIAGRAM INPUT Safe operating area protection Start-up circuit Reference voltage Error amp. Drive circuit Saturation protection OUTPUT Thermal shut down Over current protection GND 2 Data Sheet G15368EJ1VDS

ORDERING INFORMATION Part Number Package Output Voltage Marking Package Type µ PC29M33AHF MP-45G 3.3 V 29M33A Packed in envelope (Isolated TO-22) µ PC29M33AHB MP-3 (SC-64) 3.3 V 29M33A Packed in envelope µ PC29M33AT MP-3Z (SC-63) 3.3 V 29M33A Packed in envelope µ PC29M33AT-E1 MP-3Z (SC-63) 3.3 V 29M33A 16 mm wide embossed taping Pin 1 on drawout side 2 pcs/reel µ PC29M33AT -E2 MP-3Z (SC-63) 3.3 V 29M33A 16 mm width embossed taping Pin 1 at takeup side 2 pcs/reel µ PC29M33AT -T1 MP-3Z (SC-63) 3.3 V 29M33A 32 mm wide adhesive taping Pin 1 at drawout side 15 pcs/reel µ PC29M33AT -T2 MP-3Z (SC-63) 3.3 V 29M33A 32 mm wide adhesive taping Pin 1 at takeup side 15 pcs/reel µ PC29M5AHF MP-45G 5. V 29M5A Packed in envelope (Isolated TO-22) µ PC29M5AHB MP-3 (SC-64) 5. V 29M5A Packed in envelope µ PC29M5AT MP-3Z (SC-63) 5. V 29M5A Packed in envelope µ PC295AT-E1 MP-3Z (SC-63) 5. V 29M5A 16 mm wide embossed taping Pin 1 at drawout side 2 pcs/reel µ PC295AT-E2 MP-3Z (SC-63) 5. V 29M5A 16 mm wide embossed taping Pin 1 at takeup side 2 pcs/reel µ PC295AT-T1 MP-3Z (SC-63) 5. V 29M5A 32 mm wide adhesive taping Pin 1 at drawout side 15 pcs/reel µ PC295AT-T2 MP-3Z (SC-63) 5. V 29M5A 32 mm wide adhesive taping Pin 1 at takeup side 15 pcs/reel Data Sheet G15368EJ1VDS 3

ABSOLUTE MAXIMUM RATINGS (TA = 25 C unless otherwise specified) Rating Parameter Symbol µ PC29M33AHF, µ PC29M5AHF µpc29m33ahb, µpc29m5ahb µpc29m33at, µpc29m5at Unit Input Voltage VIN 2 V Internal Power Dissipation Note (TC = 25 C) PT 15 1 W Operating Ambient Temperature TA 3 to +85 C Operating Junction Temperature TJ 3 to +15 C Storage Temperature Tstg 55 to +15 C Thermal Resistance (junction to case) Rth(J-C) 7 12.5 C/W Thermal Resistance (junction to ambient) Rth(J-A) 65 125 C/W Note Internally limited. When the operating junction temperature rises over 15 C, the internal circuit shuts down the output voltage. Caution If the absolute maximum rating of any of the above parameters is exceeded even momentarily, the quality of the product may be degraded. In other words, absolute maximum ratings specify the values exceeding which the product may be physically damaged. Be sure to use the product with these ratings never exceeded. STANDARD CONNECTION D1 INPUT PC29M33A, PC29M5A OUTPUT CIN COUT + D2 CIN:.1 µf or higher. Set this value according to the length of the line between the regulator and INPUT pin. Be sure to connect CIN to prevent parasitic oscillation. Use of a film capacitor or other capacitor with excellent voltage and temperature characteristics is recommended. If using a laminated ceramic capacitor, it is necessary to ensure that CIN is.1 µf or higher for the voltage and temperature range to be used. COUT: 47 µf or higher. Be sure to connect COUT to prevent oscillation and improve excessive load regulation. Place CIN and COUT as close as possible to the IC pins (within 2 cm). Also, use an electrolytic capacitor with low impedance characteristics if considering use at sub-zero temperatures. D1: If the OUTPUT pin has a higher voltage than the INPUT pin, connect a diode. D2: If the OUTPUT pin has a lower voltage than the GND pin, connect a Schottky barrier diode. Caution Make sure that no voltage is applied to the OUTPUT pin from external. 4 Data Sheet G15368EJ1VDS

RECOMMENDED OPERATING CONDITIONS Input Voltage Parameter Symbol Type Number MIN. TYP. MAX. Unit VIN µ PC29M33A 4.3 16 V µ PC29M5A 6 16 Output Current IO All.5 A Operating Ambient Temperature TA All 3 +85 C Operating Junction Temperature TJ All 3 +125 C ELECTRICAL CHARACTERISTICS µpc29m33a (TJ = 25 C, VIN = 5 V, IO = 35 ma, CIN =.22 µf, COUT = 47 µf, unless otherwise specified) Output Voltage Parameter Symbol Conditions MIN. TYP. MAX. Unit VO 3.18 3.3 3.42 V C TJ 125 C, 4.3 V VIN 16 V, A IO 35 ma 3.14 3.46 C TJ 125 C, A IO.5 A Line Regulation REGIN 4.3 V VIN 16 V 8 33 mv Load Regulation REGL A IO.5 A 1 33 Quiescent Current IBIAS IO = A 1.8 3. ma IO =.5 A 15 2 Startup Quiescent Current IBIAS (s) VIN = 3.1 V, IO = A 9 2 ma VIN = 3.1 V, IO =.5 A 5 Quiescent Current Change IBIAS C TJ 125 C, 4.3 V VIN 16 V 2.9 15 ma Output Noise Voltage Vn 1 Hz f 1 khz 56 µ Vr.m.s. Ripple Rejection R R 4.3 V VIN 16 V, f = 12 Hz 48 64 db Dropout Voltage VDIF C TJ 125 C, IO =.5 A.5 1. V Short Circuit Current IOpeak VIN = 4.5 V.7 1.1 1.5 A VIN = 16 V.6 Peak Output Current IOpeak VIN = 4.5 V.7 1.2 1.5 A VIN = 16 V.6 1. 1.5 Temperature Coefficient of Output Voltage VO / T C TJ 125 C, IO = 5 ma.4 mv/ C Data Sheet G15368EJ1VDS 5

µpc29m5a (TJ = 25 C, VIN = 8 V, IO = 35 ma, CIN =.22 µf, COUT = 47 µf, unless otherwise specified) Output Voltage Parameter Symbol Conditions MIN. TYP. MAX. Unit VO 4.83 5. 5.18 V C TJ 125 C, 6 V VIN 16 V, A IO 35 ma 4.75 5.25 C TJ 125 C, A IO.5 A Line Regulation REGIN 6 V VIN 16 V 26 5 mv Load Regulation REGL A IO.5 A 17 5 mv Quiescent Current IBIAS IO = A 1.9 4. ma IO =.5 A 15 2 Startup Quiescent Current IBIAS (s) VIN = 4.5 V, IO = A 1 2 ma VIN = 4.5 V, IO =.5 A 5 Quiescent Current Change IBIAS C TJ 125 C, 6 V VIN 16 V 2.4 15 ma Output Noise Voltage Vn 1 Hz f 1 khz 87 µ Vr.m.s. Ripple Rejection R R 6 V VIN 16 V, f = 12 Hz 46 6 db Dropout Voltage VDIF C TJ 125 C, IO =.5 A.5 1. V Short Circuit Current IOpeak VIN = 6.5 V.65 1.1 1.5 A VIN = 16 V.6 Peak Output Current IOpeak VIN = 6.5 V.7 1.2 1.5 A VIN = 16 V.6 1.1 1.5 Temperature Coefficient of Output Voltage VO / T C TJ 125 C, IO = 5 ma.7 mv/ C 6 Data Sheet G15368EJ1VDS

TYPICAL CHARACTERISTICS (Reference Values) Pd - Total Power Dissipation - W 2 15 1 5 Without heatsink Pd vs. TA Solid line: µ PC29M33AHF, µ PC29M5AHF Broken line: µ PC29M33AHB, µ PC29M5AHB µ PC29M33AT, µ PC29M5AT With infinite heatsink 25 5 75 1 125 15 TA - Operating Ambient Temperature - C V O - Output Voltage Deviation - mv 15 1 5 5 1 15 2 5 µpc29m5a VO vs TJ µpc29m33a 5 1 15 TJ - Operating Junction Temperature - C IO = 5 ma VO - Output Voltage - V 4. 3.5 3. 2.5 2. 1.5 1. VO vs. VIN ( µ PC29M33A) I O = 5 ma TJ = 25 C I O =.35 A I O =.5 A VO - Output Voltage - V 8 7 6 5 4 3 2 VO vs. VIN ( µ PC29M5A) I O =.5 A I O =.35 A I O = 5 ma TJ = 25 C.5 1 1 2 3 4 5 6 7 8 VIN - Input Voltage - V 1 2 3 4 5 6 7 8 VIN - Input Voltage - V 5 IBIAS (IBIAS(s)) vs. VIN ( µ PC29M33A) TJ = 25 C 5 IBIAS (IBIAS(s)) vs. VIN ( µ PC29M5A) T = 25 C IBIAS - Quiescent Current - ma 4 3 2 1 I O =.35 A I O =.5 A IBIAS - Quiescent Current - ma 4 3 2 1 I O =.35 A I O =.5 A I O = A 2 4 6 8 1 12 14 16 18 2 VIN - Input Voltage - V O = A 2 4 6 8 1 12 14 16 18 2 VIN - Input Voltage - V Data Sheet G15368EJ1VDS 7

1. VDIF vs. TJ 1.5 IOpeak vs. VDIF ( µ PC29M33A) VDIF - Dropout Voltage - V.8.6.4.2 µpc29m5a µpc29m33a I O =.5 A IOpeak - Peak Output Current - A 1..5 TJ = 125 C TJ = 25 C T J = C -25 25 5 75 1 125 15 TJ - Operating Junction Temperature - C. 5 1 15 2 VDIF - Dropout Voltage - V 1.5 IOpeak vs. VDIF ( µ PC295A) 8 R R vs f IOpeak - Peak Output Current - A 1..5 TJ = C TJ = 25 C TJ = 125 C R R - Ripple Rejection - db 7 6 5 4 3 2 µpc29m33a µpc29m5a TJ = 25 C, IO =.5 A 4.3 V VIN 16 V µ PC29M33A 6 V VIN 16 V µ PC29M5A. 5 1 15 2 VDIF - Dropout Voltage - V 1 1 1 k 1 k 1 k f - Frequency - Hz 8 R. R vs. IO 1. VDIF vs. IO TJ = 25 C R. R - Ripple Rejection - db 7 6 5 4 µpc29m33a µpc29m5a TJ = 25 C, f = 12 Hz 4.3 V VIN 16 V µ PC29M33A 6 V VIN 16 V µ PC29M5A VDIF - Dropout Voltage - V.8.6.4.2 µ PC29M33A µ PC29M5A 3.1.2.3.4.5 IO - Output Current - A.1.2.3.4.5 IO - Output Current - A 8 Data Sheet G15368EJ1VDS

VO - Output Voltage - V 6 5 4 3 2 1 VO vs. IO ( µ PC29M33A) VIN = 16 V VIN = 4.3 V TJ = 25 C V = 5 V VO - Output Voltage - V 6 5 4 3 2 1 VO vs. IO ( µ PC29M5A) VIN = 16 V VIN = 6 V TJ = 25 C VIN = 8 V.2.4.6.8 1. 1.2 IO - Output Current - A.2.4.6.8 1. 1.2 IO - Output Current - A Data Sheet G15368EJ1VDS 9

PACKAGE DRAWINGS µpc29m33ahf, µpc29m5ahf 3PIN PLASTIC SIP (MP-45G) A B E N P I L D M 1 2 3 K Y H Z NOTE Each lead centerline is located within.25 mm of its true position (T.P.) at maximum material condition. F C G J M V U ITEM MILLIMETERS A 1.±.2 B 7.±.2 C 1.5±.2 D 17.±.3 E φ 3.3±.2 F.75±.1 G.25 H 2.54 (T.P.) I 5.±.3 J 2.46±.2 K 5.±.2 L 8.5±.2 M 8.5±.2 N 4.5±.2 P 2.8±.2 U 2.4±.5 V.65±.1 Y 8.9±.7 Z 1.3±.2 P3HF-254B-4 1 Data Sheet G15368EJ1VDS

µpc29m33ahb, µpc29m5ahb MP-3(SC-64) (Unit: mm) 6.5 ±.2 5.±.2 1.5 +. 2. 1 2.3±.2.5±.1 4 1.6±.2 1 2 3 5.5±.2 13.7 MIN. 1.1±.1 7. MIN..5 +.2.1.5 +.2.1 2.3 2.3.75 µpc29m33at, µpc29m5at MP-3Z (SC-63) (Unit: mm ) 4.3 MAX..8 6.5±.2 2.3±.2 5.±.2.5±.1 4 1 2 3 2. MIN. 5.5±.2 1.5 +.2.1 1. MAX. 1. MIN. 1.5 TYP. 1.1±.2.9 MAX..8 MAX..5 2.3 2.3.8 Data Sheet G15368EJ1VDS 11

RECOMMENDED SOLDERING CONDITIONS When soldering this product, it is highly recommended to observe the conditions as shown below. If other soldering processes are used, or if the soldering is perfomed under different condition, please make sure to consult with our sales offices. For more details, refer to our document SEMICONDUCTOR DEVICE MOUNTING TECHNOLOGY MANUAL (C1535E). Surface Mount Device µpc29m33at, µpc29m5at: MP-3Z (SC-63) Process Conditions Symbol Infrared Ray Reflow Vapor Phase Soldering Wave Soldering Partial Heating Method Peak temperature: 235 C or below (Package surface temperature), Reflow time: 3 seconds or less (at 21 C or higher), Maximum number of reflow processes: 2 times or less. Peak temperature: 215 C or below (Package surface temperature), Reflow time: 4 seconds or less (at 2 C or higher), Maximum number of reflow processes: 2 times or less. Solder temperature: 26 C or below, Flow time: 1 seconds or less, Maximum number of flow processes: 1 time, Pre-heating temperature: 12 C or below (Package surface temperature). Pin temperature: 3 C or below, Heat time: 3 seconds or less (Per each side of the device). IR35--2 VP15--2 WS6--1 Caution Apply only one kind of soldering condition to a device, except for "partial heating method", or the device will be damaged by heat stress. Through-hole devices µpc29m33ahf, µpc29m5ahf: MP-45G µpc29m33ahb, µpc29m5ahb: MP-3 Process Conditions Wave soldering (only to leads) Partial heating method Solder temperature: 26 C or below, Flow time: 1 seconds or less. Pin temperature: 3 C or below, Heat time: 3 seconds or less (Per each pin). Caution For through-hole device, the wave soldering process must be applied only to leads, and make sure that the package body does not get jet soldered. 12 Data Sheet G15368EJ1VDS

NOTES ON USE When the µpc29m33a, µpc29m5a are used with an input voltage that is lower than the value indicated in the recommended operating conditions, a large quiescent current flows through the device due to saturation of the transistor of the output stage. (Refer to the IBIAS (IBIAS(S)) vs. VIN curves in TYPICAL CHARACTERISTICS). These products have saturation protector, but a current of up to 8 ma MAX. may flow through the device. Thus the power supply on the input side must have sufficient capacity to allow this quiescent current to pass when the device starts up. REFERENCE DOCUMENTS Document Name Document No. QUALITY GRADE ON NEC SEMICONDUCTOR DEVICES C11531E SEMICONDUCTOR DEVICE MOUNTING TECHNOLOGY MANUAL C1535E VOLTAGE REGULATOR OF SMD SEMICONDUCTOR SELECTION GUIDE PRODUCTS AND PACKAGES G11872E X13769E Data Sheet G15368EJ1VDS 13

[MEMO] 14 Data Sheet G15368EJ1VDS

[MEMO] Data Sheet G15368EJ1VDS 15

The information in this document is current as of May, 21. The information is subject to change without notice. For actual design-in, refer to the latest publications of NEC's data sheets or data books, etc., for the most up-to-date specifications of NEC semiconductor products. Not all products and/or types are available in every country. Please check with an NEC sales representative for availability and additional information. No part of this document may be copied or reproduced in any form or by any means without prior written consent of NEC. NEC assumes no responsibility for any errors that may appear in this document. NEC does not assume any liability for infringement of patents, copyrights or other intellectual property rights of third parties by or arising from the use of NEC semiconductor products listed in this document or any other liability arising from the use of such products. No license, express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of NEC or others. Descriptions of circuits, software and other related information in this document are provided for illustrative purposes in semiconductor product operation and application examples. The incorporation of these circuits, software and information in the design of customer's equipment shall be done under the full responsibility of customer. NEC assumes no responsibility for any losses incurred by customers or third parties arising from the use of these circuits, software and information. While NEC endeavours to enhance the quality, reliability and safety of NEC semiconductor products, customers agree and acknowledge that the possibility of defects thereof cannot be eliminated entirely. To minimize risks of damage to property or injury (including death) to persons arising from defects in NEC semiconductor products, customers must incorporate sufficient safety measures in their design, such as redundancy, fire-containment, and anti-failure features. NEC semiconductor products are classified into the following three quality grades: "Standard", "Special" and "Specific". The "Specific" quality grade applies only to semiconductor products developed based on a customer-designated "quality assurance program" for a specific application. The recommended applications of a semiconductor product depend on its quality grade, as indicated below. Customers must check the quality grade of each semiconductor product before using it in a particular application. "Standard": Computers, office equipment, communications equipment, test and measurement equipment, audio and visual equipment, home electronic appliances, machine tools, personal electronic equipment and industrial robots "Special": Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster systems, anti-crime systems, safety equipment and medical equipment (not specifically designed for life support) "Specific": Aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life support systems and medical equipment for life support, etc. The quality grade of NEC semiconductor products is "Standard" unless otherwise expressly specified in NEC's data sheets or data books, etc. If customers wish to use NEC semiconductor products in applications not intended by NEC, they must contact an NEC sales representative in advance to determine NEC's willingness to support a given application. (Note) (1) "NEC" as used in this statement means NEC Corporation and also includes its majority-owned subsidiaries. (2) "NEC semiconductor products" means any semiconductor product developed or manufactured by or for NEC (as defined above). M8E. 4

2024 © technodocbox.com Privacy Policy | Terms of Service | Feedback