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Part Details for LMH6626MMX/NOPB by Texas Instruments
Results Overview of LMH6626MMX/NOPB by Texas Instruments
- Distributor Offerings: (1 listing)
- Number of FFF Equivalents: (1 replacement)
- CAD Models: (Available)
- Number of Functional Equivalents: (7 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
Consumer Electronics
Internet of Things (IoT)
Audio and Video Systems
Computing and Data Storage
Aerospace and Defense
Healthcare
Telecommunications
Automotive
LMH6626MMX/NOPB Information
LMH6626MMX/NOPB by Texas Instruments is an Operational Amplifier.
Operational Amplifiers are under the broader part category of Amplifier Circuits.
Amplifier circuits use external power to increase the amplitude of an input signal. They can be used to perform linear amplifications or logarithmic functions. Read more about Amplifier Circuits on our Amplifier Circuits part category page.
Price & Stock for LMH6626MMX/NOPB
| Part # | Distributor | Description | Stock | Price | Buy | |
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Vyrian | Peripheral ICs | 860 |
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RFQ |
Part Details for LMH6626MMX/NOPB
LMH6626MMX/NOPB CAD Models
LMH6626MMX/NOPB Part Data Attributes
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LMH6626MMX/NOPB
Texas Instruments
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Datasheet
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LMH6626MMX/NOPB
Texas Instruments
Single/ Dual Ultra Low Noise Wideband Operational Amplifier 8-VSSOP -40 to 125
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| Rohs Code | Yes | |
| Part Life Cycle Code | Obsolete | |
| Ihs Manufacturer | TEXAS INSTRUMENTS INC | |
| Part Package Code | SOIC | |
| Package Description | TSSOP, TSSOP8,.19 | |
| Pin Count | 8 | |
| Reach Compliance Code | compliant | |
| ECCN Code | EAR99 | |
| HTS Code | 8542.33.00.01 | |
| Samacsys Manufacturer | Texas Instruments | |
| Amplifier Type | OPERATIONAL AMPLIFIER | |
| Architecture | VOLTAGE-FEEDBACK | |
| Average Bias Current-Max (IIB) | 25 µA | |
| Bias Current-Max (IIB) @25C | 20 µA | |
| Common-mode Reject Ratio-Nom | 90 dB | |
| Frequency Compensation | YES | |
| Input Offset Voltage-Max | 950 µV | |
| JESD-30 Code | S-PDSO-G8 | |
| JESD-609 Code | e3 | |
| Length | 3 mm | |
| Low-Bias | NO | |
| Low-Offset | YES | |
| Micropower | NO | |
| Moisture Sensitivity Level | 1 | |
| Neg Supply Voltage Limit-Max | -6.6 V | |
| Neg Supply Voltage-Nom (Vsup) | -2.5 V | |
| Number of Functions | 2 | |
| Number of Terminals | 8 | |
| Operating Temperature-Max | 125 °C | |
| Operating Temperature-Min | -40 °C | |
| Package Body Material | PLASTIC/EPOXY | |
| Package Code | TSSOP | |
| Package Equivalence Code | TSSOP8,.19 | |
| Package Shape | SQUARE | |
| Package Style | SMALL OUTLINE, THIN PROFILE, SHRINK PITCH | |
| Packing Method | TAPE AND REEL | |
| Peak Reflow Temperature (Cel) | 260 | |
| Power | NO | |
| Programmable Power | NO | |
| Qualification Status | Not Qualified | |
| Seated Height-Max | 1.1 mm | |
| Slew Rate-Nom | 290 V/us | |
| Supply Current-Max | 36 mA | |
| Supply Voltage Limit-Max | 6.6 V | |
| Supply Voltage-Nom (Vsup) | 2.5 V | |
| Surface Mount | YES | |
| Technology | BIPOLAR | |
| Temperature Grade | AUTOMOTIVE | |
| Terminal Finish | MATTE TIN | |
| Terminal Form | GULL WING | |
| Terminal Pitch | 0.65 mm | |
| Terminal Position | DUAL | |
| Time@Peak Reflow Temperature-Max (s) | 30 | |
| Unity Gain BW-Nom | 1300000 | |
| Voltage Gain-Min | 2200 | |
| Wideband | YES | |
| Width | 3 mm |
Alternate Parts for LMH6626MMX/NOPB
This table gives cross-reference parts and alternative options found for LMH6626MMX/NOPB. 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 LMH6626MMX/NOPB, 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 |
|---|---|---|---|---|
| LMH6626MM | Texas Instruments | Check for Price | DUAL OP-AMP, 950uV OFFSET-MAX, 1300MHz BAND WIDTH, PDSO8, PLASTIC, VSSOP-8 | LMH6626MMX/NOPB vs LMH6626MM |
LMH6626MMX/NOPB Frequently Asked Questions (FAQ)
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Texas Instruments provides a recommended PCB layout in the datasheet, but it's also important to follow general high-frequency PCB design guidelines, such as keeping the signal paths short, using a solid ground plane, and avoiding vias under 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 stability, it's essential to follow the recommended compensation network and component values provided in the datasheet. Additionally, the input and output capacitors should be chosen carefully to ensure they meet the recommended values and are placed close to the device. It's also important to minimize the parasitic inductance and capacitance in the circuit.
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The maximum power dissipation of the LMH6626MMX/NOPB is dependent on the ambient temperature and the thermal resistance of the package. According to the datasheet, the maximum power dissipation is 1.4W at 25°C ambient temperature. However, it's essential to calculate the power dissipation based on the specific application and thermal conditions.
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The LMH6626MMX/NOPB is rated for operation up to 125°C junction temperature. However, the device's performance and reliability may degrade at high temperatures. It's essential to follow the recommended operating conditions and derate the device's performance accordingly. Additionally, it's recommended to consider the thermal management of the system to ensure the device operates within its recommended temperature range.
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To troubleshoot common issues, it's essential to follow a systematic approach. First, verify that the device is properly powered and the input and output voltages are within the recommended range. Next, check the compensation network and component values to ensure they meet the recommended values. Finally, use oscilloscopes and other measurement tools to identify the root cause of the issue and make adjustments accordingly.