Part Details for MP7524JN by Micro Power Systems
Results Overview of MP7524JN by Micro Power Systems
- Distributor Offerings: (1 listing)
- Number of FFF Equivalents: (10 replacements)
- CAD Models: (Request Part)
- Number of Functional Equivalents: (10 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
Education and Research
Aerospace and Defense
Agriculture Technology
Automotive
Robotics and Drones
MP7524JN Information
MP7524JN by Micro Power Systems is a Digital to Analog Converter.
Digital to Analog Converters are under the broader part category of Converters.
A converter is an electrical circuit that transforms electric energy into a different form that will support a elecrical load needed by a device. Read more about Converters on our Converters part category page.
Price & Stock for MP7524JN
| Part # | Distributor | Description | Stock | Price | Buy | |
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Bristol Electronics | 5 |
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RFQ |
Part Details for MP7524JN
MP7524JN CAD Models
MP7524JN Part Data Attributes
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MP7524JN
Micro Power Systems
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Datasheet
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Compare Parts:
MP7524JN
Micro Power Systems
D/A Converter, 1 Func, Parallel, 8 Bits Input Loading, PDIP16, PLASTIC, DIP-16
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| Part Life Cycle Code | Obsolete | |
| Ihs Manufacturer | MICRO POWER SYSTEMS | |
| Package Description | PLASTIC, DIP-16 | |
| Reach Compliance Code | unknown | |
| HTS Code | 8542.39.00.01 | |
| Analog Output Voltage-Max | 10 V | |
| Analog Output Voltage-Min | ||
| Converter Type | D/A CONVERTER | |
| Input Bit Code | BINARY | |
| Input Format | PARALLEL, 8 BITS | |
| JESD-30 Code | R-PDIP-T16 | |
| Linearity Error-Max (EL) | 0.195% | |
| Number of Bits | 8 | |
| Number of Functions | 1 | |
| Number of Terminals | 16 | |
| Operating Temperature-Max | 85 °C | |
| Operating Temperature-Min | -40 °C | |
| Package Body Material | PLASTIC/EPOXY | |
| Package Code | DIP | |
| Package Shape | RECTANGULAR | |
| Package Style | IN-LINE | |
| Qualification Status | Not Qualified | |
| Settling Time-Max | ||
| Supply Current-Max | 2 mA | |
| Supply Voltage-Nom | 5 V | |
| Surface Mount | NO | |
| Technology | CMOS | |
| Temperature Grade | INDUSTRIAL | |
| Terminal Form | THROUGH-HOLE | |
| Terminal Position | DUAL |
Alternate Parts for MP7524JN
This table gives cross-reference parts and alternative options found for MP7524JN. The Form Fit Function (FFF) tab will give you the options that are more likely to serve as direct pin-to-pin alternates or drop-in parts. The Functional Equivalents tab will give you options that are likely to match the same function of MP7524JN, but it may not fit your design. Always verify details of parts you are evaluating, as these parts are offered as suggestions for what you are looking for and are not guaranteed.
| Part Number | Manufacturer | Composite Price | Description | Compare |
|---|---|---|---|---|
| MP7524SD | Micro Power Systems | Check for Price | D/A Converter, 1 Func, Parallel, 8 Bits Input Loading, CDIP16, | MP7524JN vs MP7524SD |
| TLC7524CNE4 | Texas Instruments | Check for Price | 8-bit, 0.1-μs MDAC, parallel input, fast control signaling for DSP, easy micro interface 16-PDIP 0 to 70 | MP7524JN vs TLC7524CNE4 |
| TLC7524EN | Texas Instruments | $2.2822 | 8-bit, 0.1-μs MDAC, parallel input, fast control signaling for DSP, easy micro interface 16-PDIP -40 to 85 | MP7524JN vs TLC7524EN |
| MX7524JN | Maxim Integrated Products | Check for Price | D/A Converter, 1 Func, Parallel, 8 Bits Input Loading, PDIP16, 0.300 INCH, PLASTIC, DIP-16 | MP7524JN vs MX7524JN |
| AD7524AQ | Analog Devices Inc | Check for Price | CMOS 8-Bit Buffered Multiplying DAC | MP7524JN vs AD7524AQ |
| TLC7524IN | Texas Instruments | $3.2853 | 8-bit, 0.1-μs MDAC, parallel input, fast control signaling for DSP, easy micro interface 16-PDIP -25 to 85 | MP7524JN vs TLC7524IN |
| AD7524MJ | Texas Instruments | Check for Price | 8-Bit Multiplying DAC, Advanced LinCMOS(TM) 16-CDIP -55 to 125 | MP7524JN vs AD7524MJ |
| MX7524AD | Maxim Integrated Products | Check for Price | D/A Converter, 1 Func, Parallel, 8 Bits Input Loading, CDIP16, 0.300 INCH, SIDEBLAZE, DIP-16 | MP7524JN vs MX7524AD |
| MX7524JN+ | Analog Devices Inc | Check for Price | Improved MX7524, 16-PDIP-300_MIL, 16 Pins, 0 to 70C | MP7524JN vs MX7524JN+ |
| AD7524SQ | Analog Devices Inc | Check for Price | CMOS 8-Bit Buffered Multiplying DAC | MP7524JN vs AD7524SQ |
MP7524JN Frequently Asked Questions (FAQ)
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A good PCB layout for the MP7524JN should prioritize thermal dissipation. Place the device near a thermal pad or a heat sink, and ensure that the thermal vias are connected to a solid copper plane on the bottom layer. Keep the input and output capacitors close to the device to minimize parasitic inductance.
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To optimize output voltage accuracy, ensure that the feedback resistors (R1 and R2) have a high tolerance (e.g., 1%) and are temperature-stable. Also, use a high-quality output capacitor with low ESR and a stable capacitance over temperature. Finally, minimize the noise on the FB pin by using a low-noise voltage reference and a quiet power supply.
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Although the datasheet specifies a maximum input voltage of 24V, it's recommended to derate the input voltage to 22V to ensure reliable operation and to account for voltage spikes or transients. Exceeding the maximum input voltage can lead to device damage or failure.
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To prevent oscillations or instability, ensure that the output capacitor has a sufficient value (at least 10uF) and a low ESR. Also, add a small ceramic capacitor (e.g., 100nF) in parallel with the output capacitor to filter high-frequency noise. Finally, verify that the feedback loop is properly compensated by checking the stability of the output voltage under various load conditions.
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The recommended soft-start time for the MP7524JN is around 1-2ms. A slower soft-start time can help reduce inrush current and prevent output voltage overshoot, while a faster soft-start time can help improve startup time. However, the optimal soft-start time may vary depending on the specific application and load requirements.