PTLV9152IDR Texas Instruments Integrated Circuit (Small Outline Packages) In Stock
PTLV9152IDR is a dual rail-to-rail input/output operational amplifier with 4.5 MHz gain-bandwidth, 16 V supply range, 125 dB typical CMRR, and a maximum input offset voltage of 720 µV. The device operates in a low-profile 8-pin SOIC package and targets precision signal conditioning in industrial and consumer applications.
- Manufacturer
- Texas Instruments
- Package
- Small Outline Packages
- Pin Count
- 8
- Lifecycle
- OBSOLETE
- Datasheet
- PTLV9152IDR Datasheet PDF
- Category
- Integrated Circuit
- Temp Range
- -40.0°C to 125.0°C
- RoHS
- Compliant
- Lead Time
- 3–7 business days
- Shipping
- DHL Express · Worldwide
Key Features
- Dual op-amp with rail-to-rail input and output swing
- 4.5 MHz gain-bandwidth product for wide signal bandwidth
- Supply voltage range up to 16 V (single) or ±8 V (dual)
- 125 dB typical common-mode rejection ratio (CMRR)
- Maximum input offset voltage of 720 µV for precision use
- Low-bias input architecture reduces source impedance sensitivity
- 8-pin SOIC package compatible with standard op-amp footprints
- Voltage-feedback architecture with no external frequency compensation required
Applications
PTLV9152IDR is suited for precision signal conditioning front-ends in industrial sensor interfaces, instrumentation amplifiers, and active filter stages where rail-to-rail output swing maximizes dynamic range on single 5 V or 12 V supplies. Its low offset voltage and 125 dB CMRR make it ideal for bridge sensor amplification, transducer signal processing, and medical monitoring front-ends. The dual-channel configuration allows differential-to-single-ended conversion and two-stage filter implementations within a single 8-pin package.
Specifications
| Date Of Intro | 2019-11-22 |
| YTEOL | 0 |
| Amplifier Type | OPERATIONAL AMPLIFIER |
| Architecture | VOLTAGE-FEEDBACK |
| Common-mode Reject Ratio-Min | 110dB |
| Common-mode Reject Ratio-Nom | 125dB |
| Frequency Compensation | NO |
| Input Offset Voltage-Max | 720 µV |
| JESD-30 Code | R-PDSO-G8 |
| Low-Bias | YES |
| Low-Offset | YES |
| Micropower | YES |
| Number of Functions | 2 |
| Package Body Material | PLASTIC/EPOXY |
| Package Equivalence Code | SOP8,.23 |
| Package Shape | RECTANGULAR |
| Package Style | SMALL OUT LINE |
| Packing Method | TR |
| Power | NO |
| Programmable Power | NO |
| Slew Rate-Nom | 20V/us |
| Supply Current-Max | 1.47mA |
| Supply Voltage Limit-Max | 20V |
| Supply Voltage-Nom (Vsup) | 4V |
| Surface Mount | YES |
| Technology | BICMOS |
| Temperature Grade | AUTOMOTIVE |
| Terminal Form | GULL WING |
| Terminal Pitch | 1.27mm |
| Terminal Position | DUAL |
| Unity Gain BW-Nom | 4500 |
| Voltage Gain-Min | 158489.3192 |
| Wideband | NO |
| Package | Small Outline Packages |
Compliance & Regulatory
| RoHS Status | Compliant |
| Lead-Free | Yes (Pb-Free) |
| ECCN | EAR99 |
| HTS Code | 8542.33.00.01 |
Alternate & Equivalent Parts
Compatible alternatives and drop-in replacements for PTLV9152IDR:
Frequently Asked Questions
How does PTLV9152IDR's 125 dB CMRR benefit differential bridge sensor measurement circuits?
A 125 dB typical CMRR means PTLV9152IDR attenuates common-mode noise — such as 50 Hz or 60 Hz interference on sensor cables — by a factor of more than 560,000 relative to the differential signal. For a strain gauge bridge producing millivolt-level outputs on a 5 V supply, this level of common-mode rejection prevents power-line noise from swamping the signal, enabling accurate measurements with minimal additional filtering or shielding.
For an active low-pass filter running from a single 12 V rail, why choose PTLV9152IDR over a standard (non-rail-to-rail) op-amp?
Rail-to-rail output swing on PTLV9152IDR allows the output to reach within millivolts of both supply rails on a 12 V single supply, recovering nearly 2 V of usable output range compared to conventional op-amps limited to 1 V to 1.5 V headroom. With a 4.5 MHz gain-bandwidth product, the device supports active filter designs up to hundreds of kilohertz while the 720 µV maximum offset keeps DC bias error acceptably low for precision signal paths.
Can PTLV9152IDR replace TLV9152 in existing designs, and what does the 'P' prefix on the MPN indicate?
The 'P' prefix on PTLV9152IDR designates a prototype or pre-production grade part in Texas Instruments' naming convention, meaning it shares the same 4.5 MHz gain-bandwidth, 16 V supply limit, 125 dB CMRR, and 8-pin SOIC footprint as the production TLV9152 but may have different lot qualification status. Engineers evaluating the device should confirm production availability before committing to high-volume designs, and electrical pin compatibility allows direct substitution in prototype stages.
What maximum supply voltage and input offset voltage should designers plan for when using PTLV9152IDR in a 15 V industrial sensor interface?
PTLV9152IDR is rated for a maximum supply voltage of 16 V single-ended, making a 15 V industrial supply fully within spec with 1 V margin. The maximum input offset voltage is 720 µV, which translates to a worst-case DC error that designers should budget in gain calculations for sensor amplification stages. At a gain of 100, the 720 µV offset produces up to 72 mV of output error, so offset trimming or a higher-precision alternative may be needed for sub-millivolt measurement accuracy.
Related Guides
1206 100 uF MLCC Design Guide for Compact Bulk Decoupling
Design guidance for applying CL31A107MQHNNNE and related 1206 MLCCs in compact bulk decoupling networks.
Jul 3, 2026
0402 10 nF MLCC Design Guide for High-Speed Decoupling
Practical design guidance for using CL05B103KB5NNNC and related 0402 MLCCs in high-speed decoupling networks.
Jul 3, 2026
CL31A107MQHNNNE 1206 100 uF MLCC Selection Guide
How to choose CL31A107MQHNNNE and related 1206 MLCCs for low-voltage bulk capacitance and regulator stability.
Jul 2, 2026
CL05B103KB5NNNC 0402 10 nF X7R MLCC Selection Guide
How to choose CL05B103KB5NNNC and related 0402 MLCCs for bypassing, filtering, voltage derating, and sourcing.
Jul 2, 2026
Why Buy from FindMyChip
About Texas Instruments
Texas Instruments (TI) is a global semiconductor company headquartered in Dallas, Texas. TI designs and manufactures analog and embedded processing chips used in industrial, automotive, consumer, communications, and enterprise systems.
In Stock · 24h Response · Worldwide Shipping
Response within 24 hours · Worldwide shipping
“FindMyChip sourced our entire STM32 BOM in 48 hours when our usual distributor had 16-week lead times.”