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Transcript
OP-AMPS: NON-INVERTING AMPLIFIER & SPECIFICATIONS Prepared by: 1331_005 for Collaborative Creation of OER Target Audience: 2nd year;3rd semester Engineering Students OP-AMP SPECIFICATIONS Offset Currents and Voltages While the op-amp output should be 0 V when the input is 0 V (or equal), In actual operation there is sometimes some voltage present at the output. This voltage is known as offset voltage. The manufacturer specifies an input offset voltage for the op-amp. The output offset voltage is then determined by the input offset voltage and the gain of the amplifier, as connected by the user. The output offset voltage can be shown to be affected by two separate circuit conditions. These are: an input offset voltage, VIO , and an offset current due to the difference in currents resulting at the plus (+) and minus (-) inputs. Frequency Parameters An op-amp is designed to be a high-gain, widebandwidth amplifier. This operation tends to be unstable due to positive feedback. To ensure stable operation, op-amps are built with internal compensation circuitry, which also causes the very high open-loop gain to diminish with increasing frequency. This gain reduction is referred to as roll-off. In most op-amps, roll-off occurs at a rate of 20 dB per decade (20 dB/decade) or 6 dB per octave (6 dB/octave). The user typically connects the op-amp using feedback resistors to reduce the circuit voltage gain to a much smaller value (closed-loop voltage gain, ACL). A number of circuit improvements result from this gain reduction. The amplifier voltage gain is a more stable, precise value set by the external resistors; The input impedance of the circuit is increased over that of the op-amp alone; Third, the circuit output impedance is reduced from that of the op-amp alone; Finally, the frequency response of the circuit is increased over that of the op-amp alone. Slew Rate, SR Another parameter reflecting the op-amp’s ability to handling varying signals is slew rate defined as Maximum rate at which amplifier output can change in volts per microsecond (V/µs) The slew rate provides a parameter specifying the maximum rate of change of the output voltage when driven by a large step-input signal. If one tried to drive the output at a rate of voltage change greater than the slew rate, the output would not be able to change fast enough and would not vary over the full range expected, resulting in signal clipping or distortion. In any case, the output would not be an amplified duplicate of the input signal if the op-amp slew rate is exceeded. Common-Mode Rejection Ratio [CMRR] CMRR (common-mode rejection ratio) is the figure of merit of op-amp which express ability of the amplifier to reject the common mode signal which is defined by the following equation: an op-amp provides an output component that is due to the amplification of the difference of the signals applied to the plus and minus inputs and a component due to the signals common to both inputs. Since amplification of the opposite input signals is much greater than that of the common input signals, the circuit provides a common mode rejection as described by a numerical value called the commonmode rejection ratio (CMRR). When separate inputs are applied to the op-amp, the resulting difference signal is the difference between the two inputs When both input signals are the same, a common signal element due to the two inputs can be defined as the average of the sum of the two signals. Since any signals applied to an op-amp in general have both in-phase and out-of phase components, the resulting output can be expressed as where Vd = difference voltage Vc = common voltage Ad = differential gain of the amplifier Ac = common-mode gain of the amplifier The value of CMRR can also be expressed in logarithmic terms as It should be clear that the desired operation will have Ad very large with Ac very small. That is, the signal components of opposite polarity will appear greatly amplified at the output, whereas the signal components that are in phase will mostly cancel out so that the common-mode gain, Ac, is very small. Ideally, the value of the CMRR is infinite. Practically, the larger the value of CMRR, the better the circuit operation. REFERENCES Chapter 10:Operational Amplifiers; Electronic Devices & Circuit Theory,10/e by Robert L. Boylestad and Louis Nashelsky. “non-inverting operational amplifiers” www.electronicshub.org Chapter 08,Electrical & Electronics Systems ©Pearson Education Limited 2004 THANK YOU
