OP295 Datasheet
Rail-to-Rail Dual Op Amp
Rail-to-Rail Dual Op Amp
| Part No. | In Stock | Price | Packaging | SPQ | Marking | MSL | Pins | Temp Range | Package Description |
| OP295GPZ | 0 | $5.751 | Tube | 50 | OP295G | 1 | 8 | -40°C ~ 125°C | 8-Lead PDIP |
| OP295GSZ | 0 | $4.185 | Tube | 98 | OP295G | 1 | 8 | -40°C ~ 125°C | 8-Lead SOIC |
| OP295GSZ-REEL | 0 | $4.185 | Reel | 2500 | OP295G | 1 | 8 | -40°C ~ 125°C | 8-Lead SOIC |
| OP295GSZ-REEL7 | 5000pcs | $4.185 | Reel | 1000 | OP295G | 1 | 8 | -40°C ~ 125°C | 8-Lead SOIC |
Rail-to-rail output swing combined with dc accuracy are the key features of the OP295 dual CBCMOS operational amplifiers. By using a bipolar front end, lower noise and higher accuracy than those of CMOS designs have been achieved. Both input and output ranges include the negative supply, providing the user with zero-in/zero-out capability. For users of 3.3 V systems such as lithium batteries, the OP295 are specified for 3 V operation.
Maximum offset voltage is specified at 300 μV for 5 V operation, and the open-loop gain is a minimum of 1000 V/mV. This yields performance that can be used to implement high accuracy systems, even in single-supply designs.
The ability to swing rail-to-rail and supply 15 mA to the load makes the OP295 ideal drivers for power transistors and H bridges. This allows designs to achieve higher efficiencies and to transfer more power to the load than previously possible without the use of discrete components.
For applications such as transformers that require driving inductive loads, increases in efficiency are also possible. Stability while driving capacitive loads is another benefit of this design over CMOS rail-to-rail amplifiers. This is useful for driving coax cable or large FET transistors. The OP295/OP495 are stable with loads in excess of 300 pF.
The OP295 are specified over the extended indus-trial (−40°C to +125°C) temperature range. The OP295 is available in 8-lead PDIP and 8-lead SOIC_N surface-mount packages.