Part Details for MIC58P42YN by Microchip Technology Inc
Results Overview of MIC58P42YN by Microchip Technology Inc
- Distributor Offerings: (6 listings)
- Number of FFF Equivalents: (0 replacements)
- Tariff Estimator: (Available) NEW
- Number of Functional Equivalents: (0 options)
- CAD Models: (Request Part)
- Part Data Attributes: (Available)
- Reference Designs: (Not Available)
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MIC58P42YN Information
MIC58P42YN by Microchip Technology Inc is a Peripheral Driver.
Peripheral Drivers are under the broader part category of Drivers And Interfaces.
A driver controls the current or voltage delivered to components like LCDs or motors, while an interface component connects systems for data transfer and control. Read more about Drivers And Interfaces on our Drivers And Interfaces part category page.
Price & Stock for MIC58P42YN
| Part # | Distributor | Description | Stock | Price | Buy | |
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DISTI #
71Y2910
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Newark | 8-Bit Serial Input Protected Latched Driver 18 Pdip .300In Tube Rohs Compliant: Yes |Microchip MIC58P42YN RoHS: Compliant Min Qty: 84 Package Multiple: 1 Date Code: 0 Container: Bulk | 0 |
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$6.7500 / $7.4100 | Buy Now |
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DISTI #
MIC58P42YN
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Avnet Americas | 8-BIT SERIAL INPUT PROTECTED LATCHED DRIVER - Rail/Tube (Alt: MIC58P42YN) COO: China RoHS: Compliant Min Qty: 84 Package Multiple: 21 Lead time: 4 Weeks, 0 Days Container: Tube | 0 |
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$3.8784 / $4.3904 | Buy Now |
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DISTI #
MIC58P42YN
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Microchip Technology Inc | 8-Bit Serial Input Protected Latched Driver, PDIP, Projected EOL: 2035-10-11 COO: Thailand ECCN: EAR99 RoHS: Compliant Lead time: 7 Weeks, 0 Days Container: Tube | In Stock: 42588 and Alternates Available |
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$5.0500 / $8.6400 | Buy Now |
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DISTI #
MIC58P42YN
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TME | IC: driver, darlington,transistor array,serial input,latch Min Qty: 1 | 0 |
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$5.2100 / $7.2900 | RFQ |
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DISTI #
MIC58P42YN
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IBS Electronics | MIC58P42YN BY MICROCHIP TECHNOLOGY IS AN 8-BIT SERIAL-IN PARALLEL-OUT LATCHED DRIVER WITH OPEN-DRAIN OUTPUTS CAPABLE OF SINKING UP TO 500MA PER CHANNEL FOR DRIVING RELAYS SOLENOIDS OR LEDS IN A 20-PIN DIP PACKAGE Min Qty: 231 Package Multiple: 1 | 0 |
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$5.0960 / $5.3620 | Buy Now |
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NAC | 8-Bit Serial Input Protected Latched Driver. Package: 18 PDIP .300in TUBE - VHV ANALOG Product Line RoHS: Compliant Min Qty: 84 Package Multiple: 21 Container: Tube | 0 |
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$3.9900 / $4.8100 | Buy Now |
US Tariff Estimator: MIC58P42YN by Microchip Technology Inc
Calculations from this tool are estimations only for imports into the United States. Please refer to the distributor or manufacturer and reference official US government sources and authorities to verify any final purchase costs.
Part Details for MIC58P42YN
MIC58P42YN Part Data Attributes
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MIC58P42YN
Microchip Technology Inc
Buy Now
Datasheet
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Compare Parts:
MIC58P42YN
Microchip Technology Inc
8-Bit Serial Input Protected Latched Driver
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| Rohs Code | Yes | |
| Part Life Cycle Code | Active | |
| Package Description | Dip, Dip18,.3 | |
| Pin Count | 18 | |
| Manufacturer Package Code | PDIP-18 | |
| Reach Compliance Code | Compliant | |
| ECCN Code | EAR99 | |
| HTS Code | 8542.39.00.01 | |
| Factory Lead Time | 7 Weeks | |
| Built-in Protections | Transient; Over Current; Thermal; Under Voltage | |
| Driver Number of Bits | 8 | |
| Input Characteristics | Standard | |
| Interface IC Type | Sipo Based Peripheral Driver | |
| JESD-30 Code | R-PDIP-T18 | |
| JESD-609 Code | e3 | |
| Length | 22.86 Mm | |
| Number of Functions | 8 | |
| Number of Terminals | 18 | |
| Operating Temperature-Max | 85 °C | |
| Operating Temperature-Min | -40 °C | |
| Output Current Flow Direction | Sink | |
| Output Peak Current Limit-Nom | 0.5 A | |
| Output Polarity | Inverted | |
| Package Body Material | Plastic/Epoxy | |
| Package Code | DIP | |
| Package Equivalence Code | DIP18,.3 | |
| Package Shape | Rectangular | |
| Package Style | In-Line | |
| Seated Height-Max | 3.81 Mm | |
| Supply Current-Max | 10 Ma | |
| Supply Voltage-Nom | 5 V | |
| Surface Mount | No | |
| Technology | Bicmos | |
| Temperature Grade | Industrial | |
| Terminal Finish | Matte Tin (Sn) | |
| Terminal Form | Through-Hole | |
| Terminal Pitch | 2.54 Mm | |
| Terminal Position | Dual | |
| Width | 7.62 Mm |
MIC58P42YN Frequently Asked Questions (FAQ)
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A good PCB layout for MIC58P42YN involves keeping the input and output traces separate, using a solid ground plane, and placing decoupling capacitors close to the device. Additionally, it's recommended to use a 4-layer PCB with a dedicated power plane and a dedicated ground plane.
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To ensure proper thermal management, it's recommended to provide a heat sink or a thermal pad on the top of the device, and to ensure good airflow around the device. Additionally, the PCB should be designed to dissipate heat efficiently, and the device should be operated within its recommended temperature range.
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The recommended input capacitor value is 1-10uF, and the recommended output capacitor value is 10-100uF. The capacitor values should be chosen based on the specific application requirements, such as the output voltage, output current, and ripple voltage. A general rule of thumb is to choose a capacitor with a voltage rating at least 1.5 times the output voltage, and a capacitance value that provides a suitable ripple voltage.
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To troubleshoot common issues with MIC58P42YN, it's recommended to check the input voltage, output voltage, and output current to ensure they are within the recommended specifications. Additionally, check the PCB layout and thermal management to ensure they are properly designed. If the issue persists, check the device's internal temperature and adjust the thermal management accordingly. If the issue still persists, consult the datasheet and application notes for further guidance.
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The recommended EMI filtering components for MIC58P42YN include a common-mode choke, a differential-mode inductor, and a capacitor. To design an EMI filter, it's recommended to follow the guidelines in the datasheet and application notes, and to use simulation tools to optimize the filter design. The filter should be designed to attenuate noise in the frequency range of interest, and to meet the relevant EMI standards.