-
Part Symbol
-
Footprint
-
3D Model
Available Download Formats
By downloading CAD models, you agree to our Terms & Conditions and Privacy Policy
Part Details for MAX20474ATDA/V+ by Analog Devices Inc
Results Overview of MAX20474ATDA/V+ by Analog Devices Inc
- Distributor Offerings: (3 listings)
- Number of FFF Equivalents: (0 replacements)
- CAD Models: (Available)
- Number of Functional Equivalents: (0 options)
- Part Data Attributes: (Available)
- Reference Designs: (Not Available)
Tip: Data for a part may vary between manufacturers. You can filter for manufacturers on the top of the page next to the part image and part number.
Applications
Healthcare
Electronic Manufacturing
MAX20474ATDA/V+ Information
MAX20474ATDA/V+ by Analog Devices Inc is a Switching Regulator or Controller.
Switching Regulator or Controllers are under the broader part category of Power Circuits.
A power circuit delivers electricity in order to operate a load for an electronic device. Power circuits include transformers, generators and switches. Read more about Power Circuits on our Power Circuits part category page.
Price & Stock for MAX20474ATDA/V+
| Part # | Distributor | Description | Stock | Price | Buy | |
|---|---|---|---|---|---|---|
|
DISTI #
700-MAX20474ATDA/V+
|
Mouser Electronics | Switching Voltage Regulators Automotive low-voltage, 18Vout synchrono RoHS: Compliant | 17 |
|
$1.4300 / $2.8000 | Buy Now |
|
|
Analog Devices Inc | Automotive low-voltage, 18Vout Package Multiple: 1 | 41 |
|
$1.0700 / $4.0700 | Buy Now |
|
|
Vyrian | Other Function Semiconductors | 466 |
|
RFQ |
Part Details for MAX20474ATDA/V+
MAX20474ATDA/V+ CAD Models
MAX20474ATDA/V+ Part Data Attributes
|
|
MAX20474ATDA/V+
Analog Devices Inc
Buy Now
Datasheet
|
Compare Parts:
MAX20474ATDA/V+
Analog Devices Inc
3.0V to 5.5V Input, 6V to 18V Output, Synchronous Boost Converter, 14-LFCSP-3X3.5X0.75, 14 Pins, -40 to 125C
Select a part to compare: |
| Rohs Code | Yes | |
| Part Life Cycle Code | Active | |
| Ihs Manufacturer | ANALOG DEVICES INC | |
| Part Package Code | 14-LFCSP-3X3.5X0.75 | |
| Pin Count | 14 | |
| Manufacturer Package Code | 14-LFCSP-3X3.5X0.75 | |
| Reach Compliance Code | compliant | |
| Date Of Intro | 2021-10-30 | |
| Samacsys Manufacturer | Analog Devices | |
| Analog IC - Other Type | SWITCHING REGULATOR | |
| JESD-609 Code | e3 | |
| Moisture Sensitivity Level | 1 | |
| Peak Reflow Temperature (Cel) | 260 | |
| Terminal Finish | Matte Tin (Sn) |
MAX20474ATDA/V+ Frequently Asked Questions (FAQ)
-
A good PCB layout for the MAX20474ATDA/V+ involves keeping the input and output traces short and away from each other, using a solid ground plane, and placing decoupling capacitors close to the device. A 4-layer PCB with a dedicated power plane and a dedicated ground plane is recommended. Additionally, it's essential to follow the layout guidelines provided in the datasheet and application notes.
-
To ensure proper powering and decoupling of the MAX20474ATDA/V+, use a high-quality power supply with low noise and ripple. Decouple the device with a 10uF ceramic capacitor and a 100nF ceramic capacitor in parallel, placed as close to the device as possible. Additionally, use a 1uF ceramic capacitor to decouple the VCC pin from the analog power plane.
-
The MAX20474ATDA/V+ has an operating temperature range of -40°C to +125°C. However, the device's performance may degrade at extreme temperatures. It's essential to ensure proper thermal management and heat dissipation to maintain optimal performance.
-
To troubleshoot common issues with the MAX20474ATDA/V+, start by checking the PCB layout and ensuring that it follows the recommended guidelines. Verify that the device is properly powered and decoupled. Check for any signs of overheating or thermal issues. Use an oscilloscope to measure the output voltage and current, and look for any signs of oscillations or instability. Consult the datasheet and application notes for troubleshooting guides and FAQs.
-
The MAX20474ATDA/V+ is a high-reliability device, but it's essential to follow proper design and testing procedures to ensure its suitability for safety-critical applications. Consult the datasheet and relevant industry standards (e.g., IEC 61508, ISO 26262) for guidance on designing and testing safety-critical systems. Additionally, consider using redundant or fail-safe designs to mitigate potential risks.