CJ6330B30M

JIANGSU CHANGJING ELECTRONICS TECHNOLOGY CO., LTD 18V Low Current Consumption 300mA CMOS Voltage Regulators CJ6330 Series 1 Low-dropout Regulators Introduction The CJ6330 series is a group of low dropout linear regulators made by CMOS process. It supports the input voltage range of 2.5V to 18V, and can also provide current up to 300mA under the condition of good heat dissipation. The CJ6330 series has ultralow quiescent current and low dropout voltage, which can provide large output current even when the input and output voltage difference is very small. These features can help modern appliances meet increasingly stringent energy requirements and help extend the battery life of portable power solutions. The CJ6330 series provides a fixed voltage version with multiple output voltage points for selection. The fixed voltage version does not need external resistors and can minimize the size of printed circuit board (PCB). The CJ6330 series also has a built-in current limit and thermal shutdown, which helps to protect the regulator in the event of a load short circuit or fault. 2 3 Features • • Input Voltage Range: 2.5V ~ 18V Fixed Output Voltage Available from 1.2V to 5.0V Output Voltage Tolerance: ±2% for Conventional Device ±1% can be Customized Output Current: up to 300mA Low Quiescent Current: 2.0μA Dropout Voltage: 160mV@100mA (VOUT = 3.3V) • • • • • • Power Supply Rejection Ratio: 65dB@1kHz Low Output Noise: 27×VOUT μVRMS (10Hz ~ 100kHz) • • Excellent Transient Response Integrated Fault Protection: - Fold-back Current Limit - Thermal Shutdown - Short-Circuit Protection 4 Applications • • Always-on Power Supplies Gaming Controllers, Remote Controls,Toys, Drones Portable and Battery-powered Equipment Set-top Boxes Ultrabooks, Tablets, E-readers Wearable Electronics Wireless Handsets and Smart Phones Available Packages PART NUMBER PACKAGE SOT-23-3L SOT-89-3L CJ6330 Series • SOT-223 • • • • SOT-23-5L Note: For all available packages, please refer to the part Orderable Information. VIN 1µF IN OUT Normal Device VOUT 1µF VIN 1µF GND IN OUT With Enable Fuction EN VOUT 1µF GND Typical Application Circuits Please carefully read the notice at the end of this data sheet about product use, data sheet changes and important statements. CJ6330 Series 5 Orderable Information Package type. A□M / A□MC / A□MY: SOT-23-3L A□P / A□PT / A□PL: SOT-89-3L A□G / A□GF: SOT-223 B□M / A□MF / A□MR: SOT-23-5L CJ6330 Device serial number. Enable function marking. A: Normal device, no enable function B: With enable function Output voltage. 12: Fixed output 1.2V 15: Fixed output 1.5V 18: Fixed output 1.8V 25: Fixed output 2.5V 28: Fixed output 2.8V 30: Fixed output 3.0V 33: Fixed output 3.3V 36: Fixed output 3.6V 50: Fixed output 5.0V Figure 5-1. Naming Conventions MODEL DEVICE PACKAGE OP TEMP ECO PLAN MSL PACKING OPTION SORT 3 Pins Packaged Products CJ6330-1.2 CJ6330A12M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-1.5 CJ6330A15M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-1.8 CJ6330A18M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-2.5 CJ6330A25M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-2.8 CJ6330A28M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-3.0 CJ6330A30M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-3.3 CJ6330A33M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-3.6 CJ6330A36M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-5.0 CJ6330A50M SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330-5.0 CJ6330A50G SOT-223 -40 ~ 85°C RoHS & Green www.jscj-elec.com 2 Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 2500 Units / Reel Active Active Active Active Active Active Active Active Active Active Rev. - 2.2 CJ6330 Series 5 Orderable Information MODEL DEVICE PACKAGE OP TEMP ECO PLAN MSL PACKING OPTION Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel SORT 3 Pins Packaged Products (continued) CJ6330-1.8 CJ6330A18P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-2.5 CJ6330A25P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-2.8 CJ6330A28P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-3.0 CJ6330A30P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-3.3 CJ6330A33P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-3.6 CJ6330A36P SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330-5.0 CJ6330A50P SOT-89-3L -40 ~ 85°C RoHS & Green Active Active Active Active Active Active Active 5 Pins Packaged Products CJ6330-1.2 CJ6330B12M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-1.5 CJ6330B15M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-1.8 CJ6330B18M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-2.5 CJ6330B25M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-2.8 CJ6330B28M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-3.0 CJ6330B30M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-3.3 CJ6330B33M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-3.6 CJ6330B36M SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330-5.0 CJ6330B50M SOT-23-5L -40 ~ 85°C RoHS & Green www.jscj-elec.com 3 Active Active Active Active Active Active Active Active Active Rev. - 2.2 CJ6330 Series 5 Orderable Information MODEL DEVICE PACKAGE OP TEMP ECO PLAN MSL PACKING OPTION Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 1000 Units / Reel Level 3 Tape and Reel 168 HR 2500 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel Level 3 Tape and Reel 168 HR 3000 Units / Reel SORT Customized Products CJ6330-x.x Customized CJ6330AxxMC SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330AxxMY SOT-23-3L -40 ~ 85°C RoHS & Green CJ6330AxxPT SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330AxxPL SOT-89-3L -40 ~ 85°C RoHS & Green CJ6330AxxGF SOT-223 -40 ~ 85°C RoHS & Green CJ6330AxxMF SOT-23-5L -40 ~ 85°C RoHS & Green CJ6330AxxMR SOT-23-5L -40 ~ 85°C RoHS & Green - - -40 ~ 85°C RoHS & Green - - Customized - - - - - - Customized CJ6330-x.x ±1% grade Others Customized Customized Customized Customized Customized Customized Note: ECO PLAN: For the RoHS and Green certification standards of this product, please refer to the official report provided by JSCJ. MSL: Moisture Sensitivity Level. Determined according to JEDEC industry standard classification. SORT: Specifically defined as follows: Active: Recommended for new products; Customized: Products manufactured to meet the specific needs of customers; Preview: The device has been released and has not been fully mass produced. The sample may or may not be available; NoRD: It is not recommended to use the device for new design. The device is only produced for the needs of existing customers; Obsolete: The device has been discontinued. www.jscj-elec.com 4 Rev. - 2.2 CJ6330 Series 6 Pin Configuration and Marking Information 6.1 Pin Configuration 3 Pins SOT Series Packages PIN NAME SOT-223 SOT-89-3L SOT-23-3L SOT-23-3L SOT-89-3L SOT-223 AxxM AxxMC AxxMY AxxP AxxPT AxxPL AxxG AxxGF IN 3 1 2 2 3 1 1 3 GND 1 3 3 1 2 2 2 2 OUT 2 2 1 3 1 3 3 1 IN GND GND 3 3 3 1 2 1 2 1 2 GND OUT CJ6330AxxM SOT-23-3L IN OUT CJ6330AxxMC SOT-23-3L OUT IN CJ6330AxxMY SOT-23-3L 2 2 2 1 2 3 1 GND IN OUT CJ6330AxxP SOT-89-3L 2 3 1 OUT GND IN CJ6330AxxPT SOT-89-3L IN www.jscj-elec.com 2 3 IN GND OUT CJ6330AxxPL SOT-89-3L 2 1 2 2 3 1 GND OUT CJ6330AxxG SOT-223 2 3 OUT GND IN CJ6330AxxGF SOT-223 5 Rev. - 2.2 CJ6330 Series 6 Pin Configuration and Marking Information 6.1 Pin Configuration (continued) SOT-23-5L PIN NAME 5 Pins SOT Series Packages SOT-23-5L BxxM AxxMF AxxMR IN 1 1 2 GND 2 2 1 EN 3 - - NC 4 3&4 4&5 OUT 5 5 3 OUT NC OUT NC NC NC 5 4 5 4 5 4 3 1 3 1 1 2 IN GND EN CJ6330BxxM SOT-23-5L 2 IN GND NC CJ6330AxxMF SOT-23-5L 2 3 GND IN OUT CJ6330AxxMR SOT-23-5L 6.2 Pin Function PIN NAME CJ6330 Series Pin Function I/O DESCRIPTION Input to the device. Use the recommended value of the input capacitor and place it as close to IN I the IN and GND pins of the device as possible to help obtain the best transient response and minimize the input impedance. GND - EN I NC - Regulator ground. Enable pin. Drive EN high level to enable the device, and drive EN low level to turn off the device. Do not float this pin. If not need, connect EN to IN. No internal connection. This pin can float, but when this pin is connected to GND, the device has better thermal performance. Output of the regulator. An output capacitor needs to be placed between OUT and GND to OUT O maintain the stability of the device output. Use the capacitor with the recommended value and place it as close as possible to the OUT and GND pins of the device to help obtain the best transient response. www.jscj-elec.com 6 Rev. - 2.2 CJ6330 Series 6 Pin Configuration and Marking Information 6.3 Marking Information 3 Pins SOT Series Packages Output Voltage 1.2V 1.5V 1.8V 2.5V 2.8V 3.0V 3.3V 3.6V 5.0V Output Voltage 1.2V 1.5V 1.8V 2.5V 2.8V 3.0V 3.3V 3.6V 5.0V SOT-23-3L Conventional SOT-89-3L SOT-223 Customized Conventional Customized Conventional Customized - - - - - - - - - - - - - - - - - - - - - CJ6330A12M: DBXX CJ6330A15M: DCXX CJ6330A18M: - A7jXX CJ6330A25M: - A7qXX CJ6330A28M: - A7tXX CJ6330A30M: - A7vXX CJ6330A33M: - A7yXX CJ6330A36M: - A7bXX CJ6330A50M: - A7PXX CJ6330A18P: DDXX CJ6330A25P: DEXX CJ6330A28P: A7tXX CJ6330A30P: CJ6330A30PT: DGXX DGXXT CJ6330A33P: CJ6330A33PT: A7yXX DHXXT CJ6330A36P: - CJ6330A33GF: DHXXF - - - CJ6330A50P: CJ6330A50PT: CJ6330A50G: CJ6330A50GF: DKXX DKXXT DKXX DKXXF DIXX 5 Pins SOT Series Packages SOT-23-5L Conventional CJ6330B12M: DBXX CJ6330B15M: DCXX Customized - CJ6330B18M: CJ6330A18MR: A9jXX DDXXR CJ6330B25M: A9qXX CJ6330B28M: A9tXX CJ6330B30M: A9vXX - CJ6330B33M: CJ6330A33MR: A9yXX DHXXR CJ6330B36M: A9bXX - CJ6330B50M: CJ6330A50MR: A9PXX DKXXR www.jscj-elec.com Note: The "XX" in the marking is composed of two capital letters, which is the production date code. For example, the marking of CJ6330A33PT is "DHXXT", where "XX" is the date code of production. The date code "XX" may be different for products produced in different periods. 7 Rev. - 2.2 CJ6330 Series 7 Specifications 7.1 Absolute Maximum Ratings (TA = 25°C, unless otherwise specified)(1) CHARACTERISTIC SYMBOL VALUE UNIT Input voltage range(2) VIN -0.3 ~ 24 Enable input voltage range(2) VEN -0.3 ~ 24 Output voltage range(2) VOUT -0.3 ~ 10 PD Max Internally Limited(3) W Maximum junction temperature TJ Max 125 °C Storage temperature Tstg -40 ~ 125 °C Soldering temperature & time Tsolder 260°C, 10s - V SOT-23-3L Maximum power CJ6330 SOT-89-3L dissipation Series SOT-223 SOT-23-5L (1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Conditions. Exposure to absolute-maximum rated conditions for extended periods may affect device reliability. (2) All voltages are with respect to network ground terminal. (3) Refer to Thermal Information for details. 7.2 Recommended Operating Conditions PARAMETER SYMBOL MIN. NOM. MAX. UNIT Input voltage VIN 2.5 - 18 V Operating junction temperature TJ -40 - 125 °C Operating ambient temperature(4) TA -40 - 85 °C (4) It is necessary to ensure that the operating junction temperature of the device does not exceed the rated value of the recommended operating conditions when using the device for design. 7.3 ESD Ratings ESD RATINGS Electrostatic discharge(5) SYMBOL VALUE Human body model VESD-HBM 2000 Machine model VESD-MM 200 UNIT V (5) ESD testing is conducted in accordance with the relevant specifications formulated by the Joint Electronic Equipment Engineering Commission (JEDEC). The human body model (HBM) electrostatic discharge test is based on the JESD22-114D test standard, using a 100pF capacitor and discharging to each pin of the device through a resistance of 1.5kΩ. The electrostatic discharge test in mechanical model (MM) is based on the JESD22-115-A test standard and uses a 200pF capacitor to discharge directly to each pin of the device. www.jscj-elec.com 8 Rev. - 2.2 CJ6330 Series 7 Specifications 7.4 Thermal Information THERMAL METRIC(6) Junction-to-ambient thermal resistance Junction-to-case thermal resistance SYMBOL UNIT SOT-23-3L SOT-89-3L 261.2 159.4 SOT-223 SOT-23-5L 102.6 247.3 SOT-23-3L SOT-89-3L 65.7 54.7 SOT-223 SOT-23-5L 18.6 64.9 SOT-23-3L SOT-89-3L 0.38 0.60 SOT-223 SOT-23-5L 1.00 0.40 RΘJA RΘJC Reference maximum power dissipation for continuous CJ6330 Series PD Ref operation °C/W °C/W W (6) Thermal metric is measured in still air with TA = 25°C and installed on a 1 in2 FR-4 board covered with 2 ounces of copper. www.jscj-elec.com 9 Rev. - 2.2 CJ6330 Series 7 Specifications 7.5 Electrical Characteristics CJ6330 Series (VIN = VOUT +1V, CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) CHARACTERISTIC SYMBOL Input voltage VIN DC output tolerance - Output current IOUT Quiescent current IQ Dropout voltage VDO(9) TEST CONDITIONS MIN. TYP.(7) MAX. UNIT 2.5 - 18 V -2 - 2 -1(8) - 1(8) TJ = 25°C 300 - - mA IOUT = 0mA - 2.0 5.0 µA VOUT < 1.8V - 350 700 - 200 500 - 160 270 VOUT = 5.0V - 110 270 TA = 25°C TJ = 25°C, IOUT = 1mA VOUT = 1.8 to 2.8V VOUT = 3.0 to 3.6V IOUT = 100mA % mV Line regulation LNR(10) VIN = VOUT +1V to 18V, IOUT = 10mA - 0.01 0.3 %/V Load regulation ΔVLOAD VIN = VOUT +1V, IOUT = 1 to 100mA - 10 - mV IOUT = 10mA, TA = -40 to 125°C - 50 - ppm/°C 350 500 - mA Temperature characteristics TR(11) Output current limit ILimit VOUT = 0.5 × VOUT Normal, VIN = 5.0V Short current IShort OUT short to GND - 75 - mA Standby current ISTBY EN = GND - - 0.2 µA f = 100Hz - 75 - f = 1kHz - 65 - f = 10kHz - 50 - f = 100kHz - 40 - Power supply rejection ratio IOUT = 50mA, VIN = PSRR (VOUT +1.5V) DC + 1VPP AC - µVRMS - VIN V - - 0.3 V VIN = 5.0V, VOUT = 3.0V, EN = GND - 150 - Ω TSD - - 150 - °C ∆TSD - - 20 - °C Output noise voltage VN EN high VEN H - 1.5 EN low VEN L - COUT auto-discharge resistance Thermal shutdown Thermal shutdown hysteresis www.jscj-elec.com 27 × dB RDischarge BW = 10 to 100kHz - 10 VOUT Rev. - 2.2 CJ6330 Series 7 Specifications 7.5 Electrical Characteristics (continued) Note: (7) Typical numbers are at 25°C and represent the most likely norm. (8) Products with ±1% output tolerance can be customized. (9) Test the difference of output voltage and input voltage when input voltage is decreased gradually till output voltage equals to 98% of VOUT Normal. (10) The line regulation is calculated by the following formula: 𝐿𝐿𝐿𝐿𝐿𝐿 = ∆𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 × ∆𝑉𝑉𝐼𝐼𝐼𝐼 where, ΔVOUT is the variation of the output voltage, ΔVIN is the variation of the input voltage. (11) The output voltage temperature characteristics (TR) is calculated by the following formula: 𝑇𝑇𝐿𝐿 = ∆𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 × ∆𝑇𝑇 where, ΔVOUT is the variation of the output voltage, ΔT is the variation of the ambient temperature. 7.6 Typical Characteristics CJ6330 Series (VEN = VIN, CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) Line Regulation 700 IOUT = 10mA 5.0 DropoutVoltage VDO (mV) Output Voltage VOUT (V) 6.0 Dropout Voltage 4.0 3.0 2.0 VOUT = 1.8V VOUT = 3.3V VOUT = 5.0V 1.0 0.0 6 12 Input Voltage VIN (V) 0 500 400 300 200 100 0 18 VOUT = 1.8V VOUT = 3.3V VOUT = 5.0V 600 0 Quiescent Current 500 IOUT = 0mA 2.0 1.5 1.0 VOUT = 1.8V VOUT = 3.3V VOUT = 5.0V 0.5 0.0 0 www.jscj-elec.com 6 12 Input Voltage VIN (V) 300 GND Pin Current GND Pin Current IGND (µA) Quiescent Current IQ (µA) 2.5 100 200 Output Current IOUT (mA) 400 300 200 11 VOUT = 1.8V VOUT = 3.3V VOUT = 5.0V 100 0 18 VIN = VOUT +1V 0 100 200 Output Current IOUT (mA) Rev. - 2.2 300 CJ6330 Series 7 Specifications 7.6 Typical Characteristics (continued) CJ6330 Series (CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) Load Regulation Load Regulation 3.40 VOUT = 1.8V Output Voltage VOUT (V) Output Voltage VOUT (V) 1.90 1.85 1.80 1.75 1.70 1.65 VIN = VOUT +1V VIN = 12V 100 200 Output Current IOUT (mA) 0 3.30 3.25 3.20 3.15 3.10 300 VOUT = 3.3V 3.35 VIN = VOUT +1V VIN = 12V 0 Load Regulation Power Supply Rejection Ratio 100 VOUT = 5.0V 5.05 5.00 4.95 4.90 4.80 IOUT = 10mA IOUT = 50mA IOUT = 100mA 80 PSRR (dB) Output Voltage VOUT (V) 5.10 4.85 60 40 20 VIN = VOUT +1V VIN = 12V 0 0 300 100 200 Output Current IOUT (mA) VOUT = 1.8V VIN = (VOUT +1.5V) DC + 1 VPP AC 10 Power Supply Rejection Ratio 100 40 0 VOUT = 3.3V VIN = (VOUT +1.5V) DC + 1 VPP AC 10 www.jscj-elec.com 1k 100k Frequency f (Hz) 10M IOUT = 10mA IOUT = 50mA IOUT = 100mA 80 PSRR (dB) PSRR (dB) 100 60 20 1k 100k Frequency f (Hz) Power Supply Rejection Ratio IOUT = 10mA IOUT = 50mA IOUT = 100mA 80 300 100 200 Output Current IOUT (mA) 60 40 20 0 10M 12 VOUT = 5.0V VIN = (VOUT +1.5V) DC + 1 VPP AC 10 1k 10k Frequency f (Hz) 10M Rev. - 2.2 CJ6330 Series 7 Specifications 7.6 Typical Characteristics (continued) CJ6330 Series (CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) Load Transient VOUT = 1.8V, VIN = VEN = VOUT +1V, CH2: VOUT, CH4: IOUT IOUT: 0 ~ 100mA IOUT: 0 ~ 300mA IOUT: 10 ~ 150mA IOUT: 50 ~ 250mA VOUT = 3.3V, VIN = VEN = VOUT +1V, CH2: VOUT, CH4: IOUT IOUT: 0 ~ 100mA www.jscj-elec.com IOUT: 0 ~ 300mA 13 Rev. - 2.2 CJ6330 Series 7 Specifications 7.6 Typical Characteristics (continued) CJ6330 Series (CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) IOUT: 50 ~ 250mA IOUT: 10 ~ 150mA VOUT = 5.0V, VIN = VEN = VOUT +1V, CH2: VOUT, CH4: IOUT www.jscj-elec.com IOUT: 0 ~ 100mA IOUT: 0 ~ 300mA IOUT: 10 ~ 150mA IOUT: 50 ~ 250mA 14 Rev. - 2.2 CJ6330 Series 7 Specifications 7.6 Typical Characteristics (continued) CJ6330 Series (CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) EN High & EN Low VIN = VOUT + 1V, VEN = 0 ~ (VOUT + 1)V, IOUT = 0mA, CH2: VOUT, CH3: VEN EN high www.jscj-elec.com EN low VOUT = 1.8V VOUT = 1.8V VOUT = 5.0V VOUT = 5.0V 15 Rev. - 2.2 CJ6330 Series 7 Specifications 7.6 Typical Characteristics (continued) CJ6330 Series (CIN = 1.0µF, COUT = 1.0µF, TA = 25°C, unless otherwise specified) Power On VEN = VIN, VIN = 0 ~ (VOUT +1)V, CH1: VIN, CH2: VOUT VOUT = 1.8V, IOUT = 10mA VOUT = 1.8V, IOUT = 50mA VOUT = 3.3V, IOUT = 10mA VOUT = 3.3V, IOUT = 50mA VOUT = 5.0V, IOUT = 10mA VOUT = 5.0V, IOUT = 50mA www.jscj-elec.com 16 Rev. - 2.2 CJ6330 Series 8 Detailed Description 8.1 Description The CJ6330 series is a group of 18V, low-power consumption, low-dropout linear regulators (LDO). The CJ6330 series supports fixed voltage output from 1.2V to 5.0V, which enables it to use fewer external components to provide better accuracy. The CJ6330 series has low IQ performance and is internally integrated with current limiting, short-circuit protection and thermal shutdown protection, which makes it an ideal choice for battery power or line power applications. 8.2 Functional Block Diagram EN Enable Control IN Each Circuits + Amp Thermal Shutdown Current Limit OUT R2 VFB R1 Voltage Reference GND The internal feedback resistors R1 and R2 form a voltage divider circuit to compare the VFB input error amplifier with the reference voltage. The internal regulator tube (PMOS) will control its conduction degree through the grid voltage provided by the error amplifier output, which will make the output voltage VOUT not affected by temperature changes or input voltage changes to a certain extent, thus maintaining the stability of the device output voltage. www.jscj-elec.com 17 Rev. - 2.2 CJ6330 Series 8 Detailed Description 8.3 Feature Description Power Supply Input When the input voltage is lower than the rated range of the data sheet, the device will lose the regulation function of stabilizing the output voltage, that is, it is unable to maintain the output voltage within the rated range. At this time, compared with normal operation, the quiescent current of the device may exceed the rated range, and the transient response performance may be seriously degraded. When the input voltage is higher than the rated range of the data sheet, the device may cause irreversible damage or failure due to exceeding the maximum rated range of electrical stress. For the rated input voltage of the device, see Recommended Operating Conditions and Dropout Voltage. Output Current When the circuit design is appropriate, the CJ6330 series can reach the maximum load capacity of at least 300mA. According to the power dissipation of the package and the effective connection thermal resistance with the environment, selecting the appropriate package for the circuit design can make the device emit more heat energy. Built-in Current Limit & Short Circuit Protection The CJ6330 series has an internal current limiting circuit, which can protect the device by limiting the load current value in case of instantaneous high load current. When the current limiting is triggered, the output voltage is not regulated. If the out pin of the regulator is short circuited, the internal current limiting circuit will be triggered, the output current of the device will maintain at a relatively small value to protect the device. The typical value of short current IShort can be found in Electrical Characteristics. The current limiting state will continue until the load current drops to the normal range. When the load current of the device is large, the device will generate more heat due to the increase of power consumption, which may cause the device to turn off its output due to the internal thermal shutdown protection before the current limit is triggered. In order to ensure the normal operation of current limit, the inductance of input and load shall be minimized. Continuous operation under current limit is not recommended. The current limit mode of the CJ6330 series is fold-back current limit. Please refer to the Fold-back Current Limit for more details. Thermal Shutdown The CJ6330 series has thermal shutdown protection mechanism. When the junction temperature (TJ) of the internal main channel MOSFET exceeds the thermal shutdown threshold temperature (TSD), thermal shutdown will be triggered. At this time, the output will be turned off to prevent catastrophic damage to the chip due to accidental heating. When the TJ drops to a certain range of thermal shutdown threshold temperature (ΔTSD), the thermal shutdown will be released and the device will return to the normal output. The temperature threshold of device triggering thermal shutdown (TSD) and temperature range to be lowered to released from thermal shutdown (ΔTSD) can be found in the Electrical Characteristics. To ensure reliable operation, please limit the junction temperature to the specified range of Recommended Operating Conditions in the data sheet. Applications that exceed the recommended temperature range may cause the device to exceed its operating specifications. Although the internal protection circuit of the device is designed to prevent overall thermal conditions, it is not intended to replace proper power dissipation. Running the device continuously until thermal shutdown or higher than the recommended operating TJ will reduce long-term reliability. www.jscj-elec.com 18 Rev. - 2.2 CJ6330 Series 8 Detailed Description 8.3 Feature Description (continued) Dropout Voltage Dropout voltage (VDO) refers to the minimum voltage difference between input and output (VIN - VOUT) to make the device output voltage reach the rated range at rated current. When the dropout voltage condition required by the device is reached, the internal MOSFET will be fully turned on, at this time, the MOSFET is equivalent to a switch for regulation. The VDO increases with the increase of load current. Since VIN - VOUT must be no less than the VDO, the VDO indirectly specifies the minimum input voltage of devices under different load current conditions. If the VIN - VOUT is less than the VDO, the performance of the device may deteriorate (see Operation in Dropout Mode for details). Enable Control The enable pin of the device (EN) is active at high level. When the voltage of the EN is greater than the EN logic high voltage (VEN H), the device will be enabled and maintain the normal output. When the voltage of the EN is lower than the EN logic low voltage (VEN L), the internal circuit of the device will be disabled and the output will be turned off, the device, the device will be in the standby mode until EN is turned to high level again. The VEN H and VEN L can be found in the Electrical Characteristics. Normal startup waveform and startup slope rate control can be ensured when the device starts from any low voltage lower than VEN L, but the discharge time of output capacitor must be taken into account. EN can not be float, if EN is not required to control the output voltage independently, connect EN to IN. Auto-discharge Function The device with enable control has an auto-discharge circuit. When the enable control is turned off, the device will be disabled. An internally integrated pull-down MOSFET (see Functional Block Diagram) will connect a resistor (RDischarge) to the ground to release the charge in the output capacitor, thus closing the entire device circuit. The value of RDischarge can be found in the Electrical Characteristics. The discharge time of the output capacitor after the device is disabled is determined by the output capacitance (COUT) and load resistance (RL) in parallel with the RDischarge. The time constant τ can be calculated by the following formula: τ = C × 𝐿𝐿𝐷𝐷𝐷𝐷𝐷𝐷𝐷𝐷ℎ𝑎𝑎𝑎𝑎𝑎𝑎𝑎𝑎 (𝐿𝐿𝐿𝐿 = 0) 𝜏𝜏 = 𝐶𝐶 × � 𝐿𝐿𝐿𝐿 × 𝐿𝐿𝐷𝐷𝐷𝐷𝐷𝐷𝐷𝐷ℎ𝑎𝑎𝑎𝑎𝑎𝑎𝑎𝑎 � (𝐿𝐿𝐿𝐿 ≠ 0) 𝐿𝐿𝐿𝐿 + 𝐿𝐿𝐷𝐷𝐷𝐷𝐷𝐷𝐷𝐷ℎ𝑎𝑎𝑎𝑎𝑎𝑎𝑎𝑎 The output voltage after discharging through pull-down MOSFET can be calculated by the following formula: 𝑡𝑡 𝑉𝑉 = 𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 × 𝑒𝑒 − τ 𝑡𝑡 = τ × ln( 𝑉𝑉 ) 𝑉𝑉𝑂𝑂𝑂𝑂𝑂𝑂 Where, V is the output voltage after discharge, VOUT is the output voltage, t is the discharge time, τ is the discharge time constant. Do not rely on the active discharge circuit to release a large amount of output capacitance after the input power supply crashes, because the reverse current can flow from the output to the input. This reverse current may damage the device. The limiting reverse current shall not exceed 5% of the rated current of the device. www.jscj-elec.com 19 Rev. - 2.2 CJ6330 Series 9 Application and Implementation 9.1 Typical Application Circuits VIN IN CIN 1µF or more OUT Normal Device VOUT VIN COUT 1µF or more CIN 1µF or more IN OUT With Enable Function VOUT COUT 1µF or more EN GND GND 9.2 Application Information Selection of Bypass Capacitances For the CJ6330 series, it is recommended to use 1μF input (CIN) and output (COUT) ceramic capacitors. Type of Capacitors: Since any leakage of the capacitor will increase the quiescent power consumption of the whole circuit, attention should be paid to selecting capacitors with low leakage. When designing the circuit of portable equipment including CJ6330 series, due to the shortage of tantalum capacitors, it is a good choice to use small size, low equivalent series resistance (ESR) and high RMS current capacity multilayer ceramic capacitors (MLCC) in the DC to DC voltage conversion. The designer must choose the appropriate capacitor type for circuit design: X7R- Ceramic capacitors of X5R- and COG- rated dielectric materials can provide relatively good capacitance stability within the temperature range, Y5V- type capacitors are not recommended because of large changes in capacitance values. However, no matter which type of ceramic capacitor is selected, the effective capacitance may vary with the operating voltage and temperature. The designer must consider the influence of the change of the effective value of capacitance according to the circuit design and application conditions. Input Capacitors (CIN): It is recommended to use a 1μF capacitor at the input pin of the device, and the position of the input capacitor should be as close to the device input pin as possible. For the CJ6330 series, the input capacitor is not necessary to maintain the output stability, but it can offset the reactive input source and improve the transient response, input ripple and PSRR performance of the device. It should be noted that although many types of capacitors can be used for input bypass, using ceramic capacitors for input filtering may cause problems. Due to the self resonance and high Q characteristics of some types of ceramic capacitors, under certain starting conditions, applying voltage steps to ceramic capacitors may lead to large current surges (such as directly connecting the input pin of LDO to the power supply), which may cause some energy stored in the parasitic inductance of the power lead. When the stored energy is transferred from these inductors to ceramic capacitors, large voltage spikes may occur in the circuit. These voltage spikes are easily twice the step amplitude of the input voltage, and are likely to bring potential risks to the normal operation and reliability of the device. Therefore, the selection of ceramic capacitors as input capacitors must be careful. Adding 3Ω resistors and X5R- type ceramic capacitors will minimize voltage transients during startup. A higher value capacitor may be necessary if large, fast rise-time load or line transients are anticipated or if the device is located several inches from the input power source. www.jscj-elec.com 20 Rev. - 2.2 CJ6330 Series 9 Application and Implementation 9.2 Application Information (continued) Selection of Bypass Capacitances (continued) Output Capacitors (COUT): Recommended 1μF output ceramic capacitor to keep the device output stable, and the capacitor position should be as close to the device pin as possible. For CJ6330 series, the device needs an output capacitor to achieve loop stability. As with any regulator, a larger output capacitance reduces the peaks during a load transient but slows down the response time of the device. The proper capacitor can help to obtain better dynamic performance. Transient Response Transient response refers to the change of system output from initial state to stable state under the action of typical signal input. For LDO, the designer should pay attention to the possible impact of linear transient response and load transient response on the system: linear transient response refers to the transient response of output to change when the input voltage changes, while load transient response refers to the transient response of output to change when the output current changes. The specific phenomenon is that the output voltage of the device will have a short spike, especially when the input voltage or output current changes greatly in a short time. This change is not only related to the performance of the chip itself, but also related to the change of output current, change rate and output capacitance: 1. When the output current increases, the output voltage of the device will decrease to a certain extent, and the larger output current will provide a higher current discharge path for the output capacitor, which will affect the peak value generated by the transient spike and reduce the peak value; 2. The output current or input voltage changes relatively slowly, and the output change of the device is relatively small, affecting the spike caused by the change; 3. The use of large input and output capacitors can reduce the spike caused by transient response to a certain extent to improve the transient performance, but large output capacitors can also affect the response time of devices. For the selection of bypass capacitance value, refer to the Section of Bypass Capacitances selection. Operation in Dropout Mode The CJ6330 series is internally integrated with a P-MOSFET to achieve low dropout voltage. The voltage difference between the input and the output (VIN - VOUT) of the device must not be lower than the corresponding dropout voltage (VDO) to ensure that the output voltage tolerance is within the rated range of the data sheet. The dropout voltage will increase with the increase of load current. When the VIN - VOUT is less than the VDO, the P-MOSFET inside the device is in a linear state, the resistance from the input pin to the output pin is equal to the resistance from the drain to the source of the P-MOSFET, and the device functions like a resistor. When operating in this state, the response time of the error amplifier inside the device will be limited, which will seriously degrade the transient performance of the device, when the external circuit has a transient change, the deviation of the output voltage will become larger than the normal operating state. In addition, the PSRR and noise performance of the device will be worse than that under normal operating conditions. www.jscj-elec.com 21 Rev. - 2.2 CJ6330 Series 9 Application and Implementation 9.2 Application Information (continued) Fold-back Current Limit The CJ6330 series adopts the fold-back current limit. The following is some application information of the fold-back current limit. Current Limit Type: Current limit can impose certain restrictions on the current value provided by the device. Compared with the socalled "brick-wall" current limiting mode, the significant difference of the fold-back current limit is that overload and short circuit are obviously different. Figure 9-1 and Figure 9-2 show the typical operating characteristics of these two current limiting mechanisms. 1. Operating characteristic curve R1 represents the curve of linear resistance as load under normal working condition; 2. When the linear resistance as the load gradually decreases and causes the device to enter the overload state, the operating characteristic curve is shown in R2; 3. When the linear resistance decreases to 0Ω, the device will enter the short-circuit state, and the operating characteristic curve is shown in R3. VOUT Nor R1 Constant VOUT Nor R1 Constant R2 R2 Overload Overload R3 0 IShort IRated R3 ILimit 0 Figure 9-1. Fold-back Current Limit IRated ILimit Figure 9-2. Brick-wall Current Limit After entering the short circuit state, the short-circuit current of the "brick-wall" type current limiting mechanism is limited to ILimit, and the reliability and stability of the voltage regulator may be affected due to the large amount of heat generated during the short circuit, while the IShort of fold-back current limit in the short circuit state is far lower than ILimit, which can reduce the heat energy generated due to power dissipation during the device short circuit. The fold-back current limit allows the device to limit the short circuit current to a small current value without losing the rated range of output current. This is very important if continuous short circuit faults need to be solved. The current limiting mechanism limits the maximum load current of the device, and the internal transmission transistor of the device will not move outside its safe operation area (SOA) during operation. See Recommended Continuous Operating Areas for details. www.jscj-elec.com 22 Rev. - 2.2 CJ6330 Series 9 Application and Implementation 9.2 Application Information (continued) Fold-back Current Limit (continued) Usage and Precautions: When using the voltage regulator with the fold-back current limit, it should be noted that the device cannot be started normally under certain loads because the short-circuit current of the fold-back current limit is obviously different from the maximum load current. As shown in the curves S1 and S2 in Figure 9-3, the nonlinear load S1 is distributed in the range of the load curve region where the device can work, because the current provided by the device is always greater than the requirements of the load under all voltage conditions, the device can start normally, and the output will reach the ideal operating point P1; The situation of nonlinear load S2 is different, during actual startup, when the voltage and current are gradually rising, the output of S2 will be limited at P2, because the device cannot provide more current under the voltage at P2, which will make the output stuck at the intersection and maintain at this level, and the device cannot reach the ideal operating point P3 for normal startup. P3 S1 VOUT Nor S2 L1 VOUT Nor P1 L2 P1' P2' P2 0 P3' IShort IRated ILimit 0 Figure 9-3. Nonlinear Load Example IShort IRated ILimit Figure 9-4. Active Load Profile In addition, many typical cases of actual loads have operating characteristics as shown in L1 and L2 curves in Figure 9-4. When the device starts from zero with L1 and L2 as loads, the load will behave as a linear resistance, and the load current will change to a constant value after reaching the inflection point voltage. Like nonlinear loads S1 and S2, when L1 is used as the load, the device can start normally and reach the ideal working point P1', while when L2 is used as the load, the device cannot start normally, and the output will be stuck at P2' and cannot reach the ideal working point P3'. As an active load, the electronic load has the same operating characteristics problems may occur when using the electronic load to test the voltage regulator with See Test Current Limit for more details. For the load with specific operating characteristics as shown in S2 and L2 curves, it is back current limiting device with a higher IShort, or a voltage stabilizing device as L1 and L2. Some a fold-back current limit. necessary to use a foldwith a "brick-wall" type current limiting. www.jscj-elec.com 23 Rev. - 2.2 CJ6330 Series 9 Application and Implementation 9.2 Application Information (continued) Test Current Limit The CJ6330 series uses the fold-back current limit. When testing this kind of linear voltage regulator with the foldback current limit, it should be noted that using the electronic load that is very common in the laboratory as the load of the voltage regulator may cause some problems: 1. When the constant current mode (CC) is used for testing, when the load current is higher than the short circuit current (IShort), the device may not be able to start normally from 0V, because the CC mode of the electronic load has similar operating characteristics as the L2 curve described in the fold-back current limit. Moreover, in the CC mode, the internal circuit of the electronic load will try to pull down the output voltage below the ground. A feasible method is to start the device with no load first, and then switch to the required steady state current. A constant resistance (CR) load mode using an electronic load may help, but this may lead to the following other problems. 2. When using the CC mode of the electronic load to test the current limiting behavior, the negative feedback loop with constant internal control current of the electronic load will conflict with the current limiting loop of the device and may cause faults. When the CR mode is used for testing, the complex control loop inside the electronic load that keeps the load resistance constant will interact with the regulator and may oscillate at the output. The above are some problems that may occur when using electronic load to test the voltage regulator. Using actual resistance as the load is a good solution. When testing the ILimit, the variable resistor can be used as the load. First, set the resistance value of the variable resistor to be large enough so that the output current of the device under test at this time is significantly less than the current at full load, then gradually reduce the load resistance until the output voltage exceeds the specified range, and the load current at this time is the maximum load current. The specified range of output voltage depends on the range that the user thinks can be accepted and the current regulation rate of the voltage regulator. When some voltage regulators are in the fold-back current limit state, the output voltage drops rapidly. For these devices, the load current before the output voltage drops should be considered as the maximum load current. The measurement of short circuit current can be realized by shorting the output or connecting the load resistance of 0Ω. Compared with the electronic load, the variable resistor may not be so convenient, but the use of variable resistor for current limiting measurement is the only way to ensure that there is no bad interaction between the load and the voltage regulator. If it is necessary to measure the starting characteristics of the device, a variable resistor must be used. Recommended Continuous Operating Areas As an LDO, the working area of CJ6330 series is limited by dropout voltage, output current, junction temperature and input voltage under continuous working condition. The recommended areas for continuous operation are shown in Figure 9-5: A. The LDO input and output voltage difference VIN - VOUT must meet the dropout voltage VDO conditions. See Dropout Voltage for more details. B. Rated output current range IRated. C. The actual junction temperature TJ of LDO shall not exceed the rated junction temperature. The product of voltage difference and current at both ends of LDO is power consumption, which determines the actual working junction temperature of LDO, so the curve is not linear. In addition, the working area of CJ6330 series is limited by the rated VIN MIN and VIN MAX. www.jscj-elec.com 24 Rev. - 2.2 CJ6330 Series Application and Implementation 9.2 Application Information (continued) Recommended Continuous Work Areas (continued) Output Current 9 Output Current Limited by Dropout A Limited by VIN MIN Rated Output Current Output Current Limited by Thermals C B VIN – VOUT Limited by VIN MAX Figure 9-5. Region Description for Continuous Operation 9.3 Power Supply Recommendation The CJ6330 series is designed to operate within the input power supply voltage range of 2.5V to 18V. The input power supply should be well adjusted and have low noise. If the input power supply has high noise, it is recommended to use an additional bypass capacitor at the input to improve the output noise performance of the device. It is recommended to use an input capacitor of 1µF or higher to reduce the impedance of the input power supply, especially during transients. 9.4 Layout Guidelines When designing the circuit including CJ6330 series, the following matters should be noted: • Place the input and output capacitors as close to the pins of the device as possible; • The device is connected by copper plane and the heat sink (or back pad) of the device is fully welded with PCB to obtain better heat dissipation performance and lower on resistance; • Heat sink holes are placed around the device to help the circuit dissipate more heat energy. However, attention should be paid to the position of the heat sink holes to prevent the solder (or solder paste) on the IC pad from being absorbed by the heat sink holes and being damaged during welding. NOTE The application information in this section is not part of the data sheet component specification, and JSCJ makes no commitment or statement to guarantee its accuracy or completeness. Customers are responsible for determining the rationality of corresponding components in their circuit design and making tests and verifications to ensure the normal realization of their circuit design. www.jscj-elec.com 25 Rev. - 2.2 CJ6330 Series 10 Mechanical Information 10.1 SOT-23-3L Mechanical Information SOT-23-3L Outline Dimension Symbol Dimensions In Millimeters Dimensions In Inches Min. Max. Min. Max. A 1.050 1.250 0.041 0.049 A1 0.000 0.100 0.000 0.004 A2 1.050 1.150 0.041 0.045 b 0.300 0.500 0.012 0.020 c 0.100 0.200 0.004 0.008 D 2.820 3.020 0.111 0.119 E 2.650 1.500 2.950 1.700 0.104 0.059 0.116 0.067 E1 e 0.950(BSC) 0.037(BSC) e1 1.800 2.000 0.071 0.079 L 0.300 0.600 0.012 0.024 θ 0° 8° 0° 8° SOT-23-3L Suggested Pad Layout Note: 1. Controlling dimension: in millimeters. 2. General tolerance: ±0.05mm. 3. The pad layout is for reference purpose only. www.jscj-elec.com 26 Rev. - 2.2 CJ6330 Series 10 Mechanical Information 10.2 SOT-89-3L Mechanical Information SOT-89-3L Outline Dimensions Symbol A Dimensions In Millimeters Dimensions In Inches Min. Max. Min. Max. 1.400 1.600 0.055 0.063 b 0.320 0.520 0.013 0.197 b1 0.400 0.580 0.016 0.023 c 0.350 0.440 0.014 0.017 D 4.400 4.600 0.173 D1 1.550 REF E 2.300 E1 3.940 e L 2.600 0.091 4.250 0.155 1.500 TYP e1 1.200 0.102 0.167 0.060 TYP 3.000 TYP 0.900 0.181 0.061 REF 0.118 TYP 0.035 0.047 SOT-89-3L Suggested Pad Layout Note: 1. Controlling dimension: in millimeters. 2. General tolerance: ±0.05mm. 3. The pad layout is for reference purpose only. 1.40 0.5 2.8 1.8 1.50 www.jscj-elec.com 0 . 80 80 27 Rev. - 2.2 CJ6330 Series 10 Mechanical Information 10.3 SOT-223 Mechanical Information SOT-223 Outline Dimensions Symbol Dimensions In Millimeters Dimensions In Inches Min. Max. A —— 1.800 —— 0.071 A1 0.020 0.100 0.001 0.004 A2 1.500 1.700 0.059 0.067 b 0.660 0.840 0.026 0.033 b1 2.900 3.100 0.114 0.122 c 0.230 0.350 0.009 0.014 D 6.300 6.700 0.248 0.264 E 6.700 7.300 0.264 0.287 E1 3.300 3.700 0.130 e Min. 2.300(BSC) Max. 0.146 0.091(BSC) L 0.750 —— 0.030 —— θ 0° 10° 0° 10° SOT-223 Suggested Pad Layout Note: 1. Controlling dimension: in millimeters. 2. General tolerance: ±0.05mm. 3. The pad layout is for reference purpose only. www.jscj-elec.com 28 Rev. - 2.2 CJ6330 Series 10 Mechanical Information 10.4 SOT-23-5L Mechanical Information SOT-23-5L Outline Dimensions Symbol Dimensions In Millimeters Min. Max. Dimensions In Inches Min. Max. A 1.050 1.250 0.041 0.049 A1 0.000 0.100 0.000 0.004 A2 1.050 1.150 0.041 0.045 b 0.300 0.500 0.012 0.020 c 0.100 0.200 0.004 0.008 D 2.820 3.020 0.111 0.119 E 2.650 2.950 0.104 0.116 E1 1.500 1.700 0.950(BSC) 0.059 0.067 0.037(BSC) e1 1.800 2.000 0.071 0.079 L 0.300 0.600 0.012 0.024 θ 0° 8° 0° 8° e SOT-23-5L Suggested Pad Layout Note: 1. Controlling dimension: in millimeters. 2. General tolerance: ±0.05mm. 3. The pad layout is for reference purpose only. www.jscj-elec.com 29 Rev. - 2.2 CJ6330 Series 11 Packaging Information 11.1 SOT-23-3L Tape and Reel Information SOT-23-3L Embossed Carrier Tape Pin 1 SOT-23-3L Tape Leader and Trailer Pin 1 SOT-23-3L Reel www.jscj-elec.com 30 Rev. - 2.2 CJ6330 Series 11 Packaging Information 11.2 SOT-89-3L Tape and Reel Information SOT-89-3L Embossed Carrier Tape Pin1 SOT-89-3L Tape Leader and Trailer Pin1 SOT-89-3L Reel www.jscj-elec.com 31 Rev. - 2.2 CJ6330 Series 11 Packaging Information 11.3 SOT-223 Tape and Reel Information P1 C A E P0 d SOT-223 Embossed Carrier Tape A B F W A A A P A-A Packaging Description: SOT-223 parts are shipped in tape. The carrier tape is made from a dissipative (carbon filled) polycarbonate resin. The cover tape is a multilayer film (Heat Activated Adhesive in nature) primarily composed of polyester film, adhesive layer, sealant, and anti-static sprayed agent. These reeled parts in standard option are shipped with 2,500 units per 13" or 33.0cm diameter reel. The reels are clear in color and is made of polystyrene plastic (anti-static coated). Dimensions are in millimeter Pkg type A B C d E F P0 SOT-223 6.765 7.335 1.88 Ø1.50 1.75 5.50 4.00 P P1 W 8.00 2.00 12.00 SOT-223 Tape Leader and Trailer Trailer Tape Leader Tape Components 51±1 Empty Pockets 51±1 Empty Pockets Pin1 G SOT-223 Reel H W1 D1 D2 I W2 D Dimensions are in millimeter Reel Option D D1 D2 G H I W1 W2 13''Dia Ø330.00 100.00 13.00 R151.00 R56.00 R6.50 12.40 17.60 Carton Size(mm) G.W.(kg) REEL 2,500 pcs www.jscj-elec.com Reel Size 13 inch Box 2,500 pcs Box Size(mm) 336×336×48 32 Carton 20,000 pcs 445×355×365 Rev. - 2.2 CJ6330 Series 11 Packaging Information 11.4 SOT-23-5L Tape and Reel Information SOT-23-5L Tape and Reel Information 5 Pin 1 5 SOT-23-5L Tape Leader and Trailer SOT-23-5L Reel www.jscj-elec.com Pin1 33 Rev. - 2.2 CJ6330 Series 12 Notes and Revision History 12.1 Associated Product Family and Others To view other products of the same type or IC products of other types, click the official website of JSCJ -- https: www.jscj-elec.com for more details. 12.2 Notes Electrostatic Discharge Caution This IC may be damaged by ESD. Relevant personnel shall comply with correct installation and use specifications to avoid ESD damage to the IC. If appropriate measures are not taken to prevent ESD damage, the hazards caused by ESD include but are not limited to degradation of integrated circuit performance or complete damage of integrated circuit. For some precision integrated circuits, a very small parameter change may cause the whole device to be inconsistent with its published specifications. 12.3 Revision History July, 2023: changed from rev - 2.1 to rev - 2.2: • Page 1, changed section 2 from "Naming Conventions" to "Available Packages"; • Page 1, Features, available fixed output voltage changed to "from 1.2V to 5.0V"; • Page 2, Orderable Information, added the Naming Conventions; • Page 8, Recommended Operating Conditions, removed note 4; • Page 15, Typical Characteristics, removed the charts of the "SCP"; • Page 34, Notes, removed the notes of the thermal metric. May, 2023: changed from rev - 2.0 to rev - 2.1: • Added new device of CJ6330A18P into data sheet; • Page 9, Thermal Information, added RJC. December, 2022: changed from rev - 1.1 to rev - 2.0: • Changed the data sheet layout to JSCJ format; • Added Pin Configuration and Marking Information, ESD Ratings, Thermal Information, Detailed Description, Application and Implementation, Package Information and Notes and Revision History section; • Page 10, Electrical Characteristics, typical IShort changed from 25mA into 75mA, typical PSRR changed from 80dB@100Hz, 45dB@100kHz into 75dB@100Hz, 40dB@100kHz. www.jscj-elec.com 34 Rev. - 2.2 DISCLAIMER IMPORTANT NOTICE, PLEASE READ CAREFULLY The information in this data sheet is intended to describe the operation and characteristics of our products. JSCJ has the right to make any modification, enhancement, improvement, correction or other changes to any content in this data sheet, including but not limited to specification parameters, circuit design and application information, without prior notice. Any person who purchases or uses JSCJ products for design shall: 1. Select products suitable for circuit application and design; 2. Design, verify and test the rationality of circuit design; 3. Procedures to ensure that the design complies with relevant laws and regulations and the requirements of such laws and regulations. JSCJ makes no warranty or representation as to the accuracy or completeness of the information contained in this data sheet and assumes no responsibility for the application or use of any of the products described in this data sheet. Without the written consent of JSCJ, this product shall not be used in occasions requiring high quality or high reliability, including but not limited to the following occasions: medical equipment, military facilities and aerospace. JSCJ shall not be responsible for casualties or property losses caused by abnormal use or application of this product. Official Website: www.jscj-elec.com Copyright © JIANGSU CHANGJING ELECTRONICS TECHNOLOGY CO., LTD.