Editing Operational amplifier (section)

====Power considerations====
;[[current limiting|Limited output current]]
:The output current must be finite. In practice, most op amps are designed to limit the output current to prevent damage to the device, typically around 25&nbsp;mA for a type 741 IC op amp. Modern designs are electronically more robust than earlier implementations and some can sustain direct [[short circuit]]s on their outputs without damage.
;Limited output voltage
:Output voltage cannot exceed the power supply voltage supplied to the op amp. The maximum output of most op amps is further reduced by some amount due to limitations in the output circuitry. ''Rail-to-rail op amps'' are designed for maximum output levels.<ref name="rail-to-rail">{{cite web |url=https://www.ti.com/lit/an/sloa039a/sloa039a.pdf?ts=1623104120425&ref_url=https%253A%252F%252Fwww.google.com%252F |title=Application of Rail-to-Rail Operational Amplifiers |publisher=[[Texas Instruments]] |access-date=2021-06-08}}</ref>
;Output sink current
:The output sink current is the maximum current allowed to sink into the output stage. Some manufacturers provide an output voltage vs. the output sink current plot which gives an idea of the output voltage when it is sinking current from another source into the output pin.
;Limited dissipated power
:The output current flows through the op amp's internal output impedance, generating heat that must be dissipated. If the op amp dissipates too much power, then its temperature will increase above some safe limit. The op amp must shut down or risk being damaged.
Modern integrated [[FET]] or [[MOSFET]] op amps approximate more closely the ideal op amp than bipolar ICs when it comes to input impedance and input bias currents. Bipolars are generally better when it comes to input ''voltage'' offset, and often have lower noise. Generally, at room temperature, with a fairly large signal, and limited bandwidth, FET and MOSFET op amps now offer better performance.