Description
THS4011CD Texas Instruments - Yeehing Electronics
290-MHz Low-Distortion Voltage-Feedback Amplifier
Pricing (USD)
Quantity | Unit Price |
1 — 99 | 4.447 |
100 — 249 | 3.626 |
250 — 999 | 2.85 |
1,000 + | 1.69 |
The above prices are for reference only.
Specifications
Manufacturer | Texas Instruments |
Product Category | High Speed Operational Amplifiers |
RoHS | Y |
Series | THS4011 |
Number of Channels | 1 Channel |
GBP - Gain Bandwidth Product | 270 MHz |
SR - Slew Rate | 310 V/us |
Voltage Gain dB | 81.58 dB |
CMRR - Common Mode Rejection Ratio | 82 dB to 110 dB |
Ib - Input Bias Current | 6 uA |
Vos - Input Offset Voltage | 6 mV |
Supply Voltage - Max | 33 V |
Supply Voltage - Min | 9 V |
Operating Supply Current | 9.5 mA |
Minimum Operating Temperature | - 40 C |
Maximum Operating Temperature | + 85 C |
Mounting Style | SMD/SMT |
Package / Case | MSOP-PowerPad-8 |
Packaging | Reel |
Height | 1.02 mm |
Length | 3 mm |
Product | Operational Amplifiers |
Width | 3 mm |
Brand | Texas Instruments |
en - Input Voltage Noise Density | 7.5 nV/sqrt Hz |
Operating Supply Voltage | 33 V |
Pd - Power Dissipation | 2140 mW |
Product Type | Op Amps - High Speed Operational Amplifiers |
PSRR - Power Supply Rejection Ratio | 75 dB |
Factory Pack Quantity | 2500 |
Subcategory | Amplifier ICs |
Unit Weight | 0.000861 oz |
For more information, please refer to datasheet
Documents
THS4011CD Datasheet |
More Information
The THS4011 and THS4012 are high-speed, single/dual, voltage feedback amplifiers ideal for a wide range of applications. The devices offer good ac performance, with 290-MHz bandwidth, 310-V/µs slew rate, and 37-ns settling time (0.1%). These amplifiers have a high output drive capability of 110 mA and draw only 7.8-mA supply current per channel. For applications requiring low distortion, the THS4011/4012 operate with a total harmonic distortion (THD) of -80 dBc at f = 1 MHz. For video applications, the THS4011/4012 offer 0.1-dB gain flatness to 70 MHz, 0.006% differential gain error, and 0.01° differential phase error.