Part Details for ZXMP10A13FTC by Zetex / Diodes Inc
Results Overview of ZXMP10A13FTC by Zetex / Diodes Inc
- Distributor Offerings: (1 listing)
- 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
Energy and Power Systems
Transportation and Logistics
Renewable Energy
Automotive
ZXMP10A13FTC Information
ZXMP10A13FTC by Zetex / Diodes Inc is a Small Signal Field-Effect Transistor.
Small Signal 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 ZXMP10A13FTC
| Part # | Distributor | Description | Stock | Price | Buy | |
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DISTI #
61708709
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Verical | Trans MOSFET P-CH 100V 0.7A 3-Pin SOT-23 T/R RoHS: Compliant Min Qty: 577 Package Multiple: 1 Date Code: 2144 | Americas - 4402 |
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$0.0875 / $0.1072 | Buy Now |
Part Details for ZXMP10A13FTC
ZXMP10A13FTC CAD Models
ZXMP10A13FTC Part Data Attributes
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ZXMP10A13FTC
Zetex / Diodes Inc
Buy Now
Datasheet
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ZXMP10A13FTC
Zetex / Diodes Inc
Small Signal Field-Effect Transistor, 0.7A I(D), 100V, 1-Element, P-Channel, Silicon, Metal-oxide Semiconductor FET, SOT-23, 3 PIN
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| Rohs Code | Yes | |
| Part Life Cycle Code | Transferred | |
| Ihs Manufacturer | ZETEX PLC | |
| Package Description | SOT-23, 3 PIN | |
| Reach Compliance Code | compliant | |
| ECCN Code | EAR99 | |
| Configuration | SINGLE WITH BUILT-IN DIODE | |
| DS Breakdown Voltage-Min | 100 V | |
| Drain Current-Max (ID) | 0.7 A | |
| Drain-source On Resistance-Max | 1 Ω | |
| FET Technology | METAL-OXIDE SEMICONDUCTOR | |
| JESD-30 Code | R-PDSO-G3 | |
| JESD-609 Code | e3 | |
| Moisture Sensitivity Level | 1 | |
| Number of Elements | 1 | |
| Number of Terminals | 3 | |
| Operating Mode | ENHANCEMENT MODE | |
| Operating Temperature-Max | 150 °C | |
| Package Body Material | PLASTIC/EPOXY | |
| Package Shape | RECTANGULAR | |
| Package Style | SMALL OUTLINE | |
| Peak Reflow Temperature (Cel) | 260 | |
| Polarity/Channel Type | P-CHANNEL | |
| Power Dissipation-Max (Abs) | 0.625 W | |
| Qualification Status | Not Qualified | |
| Surface Mount | YES | |
| Terminal Finish | Matte Tin (Sn) | |
| Terminal Form | GULL WING | |
| Terminal Position | DUAL | |
| Time@Peak Reflow Temperature-Max (s) | 40 | |
| Transistor Application | SWITCHING | |
| Transistor Element Material | SILICON |
ZXMP10A13FTC Frequently Asked Questions (FAQ)
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A good PCB layout for the ZXMP10A13FTC should include a solid ground plane, short and wide traces for the input and output, and a decoupling capacitor (e.g., 100nF) between the input and ground. Additionally, keep the device away from high-frequency noise sources and ensure good thermal dissipation.
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To ensure stable operation, follow the recommended operating conditions, including the input voltage range (10-13V) and current limit (1A). Also, ensure good thermal management by providing adequate heat sinking and airflow. The device is rated for operation from -40°C to 125°C, so design your system to stay within these limits.
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The ZXMP10A13FTC can withstand input voltage transients up to 15V for a maximum duration of 100ms. However, it's recommended to keep the input voltage within the specified operating range (10-13V) to ensure reliable operation and prevent damage to the device.
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While the ZXMP10A13FTC is a high-quality device, it's essential to evaluate its suitability for high-reliability or automotive applications. Check the device's AEC-Q100 qualification and ensure it meets the specific requirements of your application, including temperature range, vibration, and other environmental factors.
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To calculate the power dissipation, use the formula: Pd = (Vin - Vout) x Iout. Then, use the thermal resistance (RθJA) and the calculated power dissipation to estimate the junction temperature (Tj) using the formula: Tj = Tc + (RθJA x Pd), where Tc is the case temperature.