The Ideal Integrator
The ideal integrator, shown in Fig. 1, with symbol shown in Fig. 2, makes use of an ideal operational amplifier with , , and .
Figure 1: The op-amp-based ideal integrator.
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Figure 2: The symbol for an integrator.
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The current through the resistor, , can be expressed as:
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(1)
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Thus, we can write the integrator output voltage, , as:
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(2)
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In the Laplace domain:
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(3)
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Or equivalently:
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(4)
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The magnitude and phase response of an ideal integrator is shown in Figs. 3 and 4. A key feature to note in ideal integrators is the fact that:
- The unity gain frequency is equal to , and
- The phase at the unity gain frequency is exactly .
Figure 3: Magnitude response of an ideal integrator with .
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Figure 4: Phase response of an ideal integrator with .
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Rewriting the transfer function as:
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(5)
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We can then define the quality factor of an ideal integrator:
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(6)
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Since . Fig. 5 shows a two-input integrator, with output voltage:
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(7)
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Figure 5: A two-input op-amp integrator.
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Integrator Noise
Fig. 6 shows an integrator where the output is fed back to one of its inputs, giving us:
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(8)
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Figure 6: Resistor thermal noise generators in an integrator.
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Ignoring the noise from the amplifier, the output noise of the integrator in Fig. 6 can be expressed as:
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(9)
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The total integrated noise is then:
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(10)
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Integrator Non-Idealities
In practice, integrators are limited by the characteristics of non-ideal amplifiers: (1) finite gain at DC, and (2) non-dominant amplifier poles. Let us look at the effects of these non-idealities one at a time.
Finite Gain
The transfer function of an integrator using an amplifier with finite gain, , can be written as:
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(11)
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The magnitude and phase response of this non-ideal integrator is shown in Figs. 7 and 8.
Figure 7: The magnitude response of an integrator with a finite-gain amplifier.
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Figure 8: The phase response of an integrator with a finite-gain amplifier.
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Note that the integrator quality factor now becomes finite:
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(12)
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The phase at is then:
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(13)
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Thus, if is finite, will approach, but will never be equal to , resulting in a phase lead. For example, if , we get , and will result in .
Non-Dominant Poles
The transfer function of an integrator using an amplifier with infinite gain but with non-dominant poles can be expressed as:
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(14)
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The magnitude and phase response of this non-ideal integrator is shown in Figs. 9 and 10.
Figure 9: The magnitude response of an integrating using an amplifier with a non-dominant pole, .
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Figure 10: The phase response of an integrating using an amplifier with a non-dominant pole, .
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The phase at the unity gain frequency is then equal to:
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(15)
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Note that the non-dominant poles contribute to the integrator phase lag.
In a real integrator, the effects (phase lead) of the amplifier finite gain can cancel out the effects (phase lag) of the non-dominant poles! Given the transfer function of the integrator with an amplifier that has both finite gain and non-dominant poles:
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(16)
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If we assume that and , we can then rewrite the transfer function as:
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(17)
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For non-dominant poles. The integrator quality factor is then equal to:
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(18)
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As expected, the effect of finite gain can be cancelled out by the effect of the non-dominant poles.
Capacitor Non-Idealities
For lossy capacitors, modeled in Fig. 11 as an ideal capacitor in series with a resistor, , the integrator transfer function becomes:
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(19)
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The magnitude and phase response is shown in Figs. 12 and 13. Notice the phase lead introduced by the zero due to . At :
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(20)
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The integrator quality factor can then be written as:
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(21)
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Thus, a non-zero degrades the integrator quality factor, but in typical implementations, the amplifier non-idealities will dominate.
Summary
The quality factor of the integrator is reduced by:
- The finite gain of the amplifier,
- The presence of amplifier non-dominant poles, and
- The loss of passive reactive components, e.g. capacitors.
Note that both the finite amplifier gain and the lossy capacitor introduces a phase lead, and the presence of non-dominant poles results in a phase lag.