Part Details for 2308-1HPGG by Integrated Device Technology Inc
Results Overview of 2308-1HPGG by Integrated Device Technology Inc
- Distributor Offerings: (1 listing)
- Number of FFF Equivalents: (8 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.
2308-1HPGG Information
2308-1HPGG by Integrated Device Technology Inc is a Clock Driver.
Clock Drivers are under the broader part category of Logic Components.
Digital logic governs the behavior of signals in electronic circuits, enabling complex decisions based on simple binary inputs (yes/no). Logic components perform operations from these signals. Read more about Logic Components on our Logic part category page.
Price & Stock for 2308-1HPGG
| Part # | Distributor | Description | Stock | Price | Buy | |
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DISTI #
70216324
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RS | 3.3V PLL ZERO DELAY CLOCK MULTIPLEXER Min Qty: 384 Package Multiple: 1 Container: Bulk | 0 |
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$1.3010 / $1.3690 | RFQ |
Part Details for 2308-1HPGG
2308-1HPGG CAD Models
2308-1HPGG Part Data Attributes
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2308-1HPGG
Integrated Device Technology Inc
Buy Now
Datasheet
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Compare Parts:
2308-1HPGG
Integrated Device Technology Inc
TSSOP-16, Tube
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| Pbfree Code | Yes | |
| Rohs Code | Yes | |
| Part Life Cycle Code | Transferred | |
| Ihs Manufacturer | INTEGRATED DEVICE TECHNOLOGY INC | |
| Part Package Code | TSSOP | |
| Package Description | TSSOP-16 | |
| Pin Count | 16 | |
| Manufacturer Package Code | PGG16 | |
| Reach Compliance Code | compliant | |
| ECCN Code | EAR99 | |
| HTS Code | 8542.39.00.01 | |
| Family | 2308 | |
| Input Conditioning | STANDARD | |
| JESD-30 Code | R-PDSO-G16 | |
| JESD-609 Code | e3 | |
| Logic IC Type | PLL BASED CLOCK DRIVER | |
| Max I(ol) | 0.012 A | |
| Moisture Sensitivity Level | 1 | |
| Number of Functions | 1 | |
| Number of Inverted Outputs | ||
| Number of Terminals | 16 | |
| Number of True Outputs | 8 | |
| Operating Temperature-Max | 70 °C | |
| Operating Temperature-Min | ||
| Output Characteristics | 3-STATE | |
| Package Body Material | PLASTIC/EPOXY | |
| Package Code | SOP | |
| Package Equivalence Code | TSSOP16,.25 | |
| Package Shape | RECTANGULAR | |
| Package Style | SMALL OUTLINE | |
| Peak Reflow Temperature (Cel) | 260 | |
| Qualification Status | Not Qualified | |
| Same Edge Skew-Max (tskwd) | 0.2 ns | |
| Supply Voltage-Max (Vsup) | 3.6 V | |
| Supply Voltage-Min (Vsup) | 3 V | |
| Supply Voltage-Nom (Vsup) | 3.3 V | |
| Surface Mount | YES | |
| Temperature Grade | COMMERCIAL | |
| Terminal Finish | MATTE TIN | |
| Terminal Form | GULL WING | |
| Terminal Pitch | 0.635 mm | |
| Terminal Position | DUAL | |
| Time@Peak Reflow Temperature-Max (s) | 30 | |
| fmax-Min | 133.3 MHz |
Alternate Parts for 2308-1HPGG
This table gives cross-reference parts and alternative options found for 2308-1HPGG. 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 2308-1HPGG, 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 |
|---|---|---|---|---|
| 2308B-1HPGG | Integrated Device Technology Inc | Check for Price | TSSOP-16, Tube | 2308-1HPGG vs 2308B-1HPGG |
| 2308-5HPGGI8 | Integrated Device Technology Inc | Check for Price | TSSOP-16, Reel | 2308-1HPGG vs 2308-5HPGGI8 |
| IDT2308A-1HPGG8 | Integrated Device Technology Inc | Check for Price | PLL Based Clock Driver, 2308 Series, 8 True Output(s), 0 Inverted Output(s), PDSO16, LEAD FREE, TSSOP-16 | 2308-1HPGG vs IDT2308A-1HPGG8 |
| IDT2308-1HPGG | Renesas Electronics Corporation | Check for Price | PLL Based Clock Driver, 2308 Series, 8 True Output(s), 0 Inverted Output(s), PDSO16 | 2308-1HPGG vs IDT2308-1HPGG |
| IDT23S08-5HPG | Integrated Device Technology Inc | Check for Price | PLL Based Clock Driver, 23S Series, 8 True Output(s), 0 Inverted Output(s), PDSO16, TSSOP-16 | 2308-1HPGG vs IDT23S08-5HPG |
| 2308B-1HPGGI8 | Renesas Electronics Corporation | Check for Price | 3.3V Zero Delay Clock Multiplier, TSSOP0/Reel | 2308-1HPGG vs 2308B-1HPGGI8 |
| MPC962308DT-1HR2 | Integrated Device Technology Inc | Check for Price | PLL Based Clock Driver, 962308 Series, 8 True Output(s), 0 Inverted Output(s), CMOS, PDSO16, 0.150 INCH, TSSOP-16 | 2308-1HPGG vs MPC962308DT-1HR2 |
| IDT23S08-3PGI | Renesas Electronics Corporation | Check for Price | PLL Based Clock Driver, 23S Series, 8 True Output(s), 0 Inverted Output(s), PDSO16 | 2308-1HPGG vs IDT23S08-3PGI |
2308-1HPGG Frequently Asked Questions (FAQ)
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A good PCB layout for the 2308-1HPGG involves keeping the input and output traces short and separate, using a solid ground plane, and placing decoupling capacitors close to the device. It's also recommended to follow the layout guidelines provided in the application note AN-803.
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To ensure proper powering and decoupling, use a high-quality power supply with low noise and ripple. Add decoupling capacitors (e.g., 0.1uF and 10uF) close to the device, and consider adding a 10nF capacitor between the VCC and GND pins. Also, ensure the power supply can provide the required current for the device.
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The 2308-1HPGG has an operating temperature range of -40°C to +85°C. However, it's recommended to operate the device within a temperature range of 0°C to +70°C for optimal performance and reliability.
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While the 2308-1HPGG is a robust device, it's not specifically designed for high-vibration environments. If you need to use it in such an environment, ensure the device is properly secured to the PCB, and consider adding additional mechanical support or vibration dampening measures.
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To troubleshoot issues with the 2308-1HPGG, start by checking the power supply and decoupling capacitors. Verify that the input and output signals are within the specified ranges, and check for any signs of overheating or physical damage. Use an oscilloscope to analyze the signal waveforms and identify any anomalies.