Part Details for APT5010JN by Microchip Technology Inc
Results Overview of APT5010JN by Microchip Technology Inc
- Distributor Offerings: (2 listings)
- Number of FFF Equivalents: (0 replacements)
- CAD Models: (Request Part)
- Number of Functional Equivalents: (0 options)
- Part Data Attributes: (Available)
- Reference Designs: (Not Available)
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Applications
Consumer Electronics
Industrial Automation
Energy and Power Systems
Renewable Energy
Motor control systems
APT5010JN Information
APT5010JN by Microchip Technology Inc is a Power Field-Effect Transistor.
Power Field-Effect Transistors are under the broader part category of Transistors.
A transistor is a small semiconductor device used to amplify, control, or create electrical signals. When selecting a transistor, factors such as voltage, current rating, gain, and power dissipation must be considered, with common types. Read more about Transistors on our Transistors part category page.
Price & Stock for APT5010JN
| Part # | Distributor | Description | Stock | Price | Buy | |
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NAC | FG, MOSFET, 500V, 0.10_OHM, SOT-227 RoHS: Compliant Min Qty: 10 Package Multiple: 1 Container: Tube | 0 |
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RFQ | |
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DISTI #
APT5010JN
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Richardson RFPD | POWER MOSFET TRANSISTOR RoHS: Compliant Min Qty: 1 | 0 |
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RFQ |
Part Details for APT5010JN
APT5010JN CAD Models
APT5010JN Part Data Attributes
APT5010JN Frequently Asked Questions (FAQ)
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Microchip recommends a 2-layer PCB with a solid ground plane on the bottom layer and a thermal relief pattern on the top layer to ensure good heat dissipation. A minimum of 2 oz copper thickness is recommended.
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To ensure reliable operation at high temperatures, it's essential to follow proper thermal design and layout guidelines, use a heat sink if necessary, and ensure the device is operated within its specified temperature range (–40°C to +150°C).
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The maximum allowed voltage on the VCC pin is 5.5V. Exceeding this voltage can cause permanent damage to the device.
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To handle the high current output, use a suitable PCB layout with wide traces, and consider using a heat sink or thermal interface material to dissipate heat. Additionally, ensure the output pins are connected to a suitable load or current-limiting device.
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Microchip recommends using a 10uF to 22uF ceramic capacitor with an X7R or X5R dielectric, placed as close as possible to the VIN pin, to filter the input voltage and reduce noise.