Description
TLC27L1CDR Texas Instruments - Yeehing Electronics
Single, 16-V, 85-kHz, low power (10-μA/ch), In to V- operational amplifier
Pricing (USD)
| Quantity | Unit Price |
| 1 — 99 | 1.331 |
| 100 — 249 | 1.024 |
| 250 — 999 | 0.754 |
| 1,000 + | 0.43 |
The above prices are for reference only.
Specifications
| Manufacturer | Texas Instruments |
| Product Category | Precision Amplifiers |
| RoHS | Y |
| Series | TLC27L1 |
| Number of Channels | 1 Channel |
| GBP - Gain Bandwidth Product | 85 kHz |
| SR - Slew Rate | 0.03 V/us |
| CMRR - Common Mode Rejection Ratio | 65 dB to 94 dB |
| Ib - Input Bias Current | 60 pA |
| Vos - Input Offset Voltage | 10 mV |
| en - Input Voltage Noise Density | 68 nV/sqrt Hz |
| Supply Voltage - Max | 16 V |
| Supply Voltage - Min | 3 V |
| Operating Supply Current | 10 uA |
| Minimum Operating Temperature | - 40 C |
| Maximum Operating Temperature | + 85 C |
| Shutdown | No Shutdown |
| Mounting Style | SMD/SMT |
| Package / Case | SOIC-8 |
| Packaging | Reel |
| Amplifier Type | Low Power Amplifier |
| Height | 1.58 mm |
| Input Type | Rail-to-Rail |
| Length | 4.9 mm |
| Product | Precision Amplifiers |
| Supply Type | Single |
| Technology | CMOS |
| Width | 3.91 mm |
| Brand | Texas Instruments |
| Operating Supply Voltage | 3 V to 16 V |
| Pd - Power Dissipation | 725 mW |
| Product Type | Precision Amplifiers |
| Factory Pack Quantity | 2500 |
| Subcategory | Amplifier ICs |
| Tradename | LinCMOS |
| Vcm - Common Mode Voltage | Negative Rail - 0.2 V to Positive Rail - 1 V |
| Voltage Gain dB | 114.32 dB |
| Unit Weight | 0.002561 oz |
For more information, please refer to datasheet
Documents
| TLC27L1CDR Datasheet |
More Information
The TLC27L1 operational amplifier combines a wide range of input offset-voltage grades with low offset-voltage drift and high input impedance. In addition, the TLC27L1 is a low-bias version of the TLC271 programmable amplifier. These devices use the Texas Instruments silicon-gate LinCMOS technology, which provides offset-voltage stability far exceeding the stability available with conventional metal-gate processes.
