User:Omegatron/opamps

This page is no longer of importance.

Contents

1 Common Configurations (with breaks) 2 Common Configurations (with headers) 2.1 Inverting amplifier 2.2 Non-inverting amplifier 2.3 Voltage follower 2.4 Difference amplifier 2.5 Summing amplifier 2.6 Integrator 2.7 Differentiator 2.8 Comparator 2.9 Schmitt trigger 2.10 Inductance gyrator

Common Configurations (with breaks)

The resistors used in these configurations are typically in the kΩ range. <1 kΩ range resistors cause excessive current flow and possible damage to the device. >1 MΩ range resistors cause excessive thermal noise and bias currents.

Z_out for all of the amplifiers is ideally 0 Ω. Realistically, it is 1 Ω to 1 kΩ, depending on the device.

---

Inverting amplifier
Missing image
Opampinverting.png
Inverting Amplifier

• Inverts and amplifies a voltage (multiplies by a negative constant)
• V_out = −V_in (R_f / R_in)
• Z_in = R_in (because V₋ is a virtual ground)

---

Non-inverting amplifier
Missing image
Opampnoninverting.png
Non-Inverting Amplifier

• Amplifies a voltage (multipies by a constant greater than 1)
• V_out = V_in (1 + R₂ / R₁)
• Z_in = ∞ (realistically, the input impedance of the op-amp itself, 1 MΩ to 10¹² Ω)

---

Voltage follower
Missing image
Opampfollowing.png
Voltage Follower

• Used as a buffer, to eliminate loading effects or to interface impedances (connecting a device with a high source impedance to a device with a low input impedance)
• V_out = V_in
• Z_in = ∞ (realistically, the input impedance of the op-amp itself, 1 MΩ to 10¹² Ω)

---

Difference amplifier

• For independent R₁,R₂,R₃,R₄ (differential amplifier):
  • <math> V_{out} = V_2 \left( { \left( R_3 + R_1 \right) R_4 \over \left( R_4 + R_2 \right) R_1} \right) - V_1 \left( {R_3 \over R_1} \right) <math>
• For R₁ = R₂ and R₃ = R₄ (amplified difference),
  • <math> V_{out} = {R_3 \over R_1} \left( V_2 - V_1 \right) <math>
• For R₁ = R₃ and R₂ = R₄ (also for R₁ = R₂ = R₃ = R₄) (difference amplifier):
  • <math> V_{out} = V_2 - V_1 \,\!<math>
• Differential Z_in (between the two input pins) = R₁ + R₂
• An instrumentation amplifier is made by adding a voltage follower to each input to increase the input impedance.

---

Summing amplifier

• Sums several (weighted) voltages
• Output is inverted
• For independent R₁, R₂, ... R_n
  • V = − R_f (V₁ / R₁ + V₂ / R₂ + ... + V_n / R_n)
• For R₁ = R₂ = ... = R_n, and R_F independent
  • V = − (R_f / R₁) (V₁ + V₂ + ... + V_n)
• For R₁ = R₂ = ... = R_n = R_f
  • V = − (V₁ + V₂ + ... + V_n)
• Input impedance Z_n = R_n, for each input (V₋ is a virtual ground)

---

Integrator

• Integrates the signal over time (where V_in and V_out are functions of time)
• <math> V_{out} = \int_0^t - {V_{in} \over RC} \, dt + V_{initial} <math>
  (V_initial is the output voltage of the integrator at time t = 0.)
• Note that this can also be viewed as a type of electronic filter.

---

Differentiator
Missing image
Opampdifferentiating.png
Differentiating Amplifier

• Differentiates the signal over time (where V_in and V_out are functions of time)
• <math> V_{out} = - R C \, {d V_{in} \over dt} <math>
• Note that this can also be viewed as a type of electronic filter.

---

Comparator
Missing image
Opampcomparator.png
Comparator

• Compares two voltages and outputs one of two states depending on which is greater
• <math> V_{out} = \left\{\begin{matrix} V_{S+} & V_1 > V_2 \\ V_{S-} & V_1 < V_2 \end{matrix}\right. <math>
• See article for details

---

Schmitt trigger

• A comparator with hysteresis
• See article for details

---

Inductance gyrator

• Simulates an inductor
• See article for details

Common Configurations (with headers)

The resistors used in these configurations are typically in the kΩ range. <1 kΩ range resistors cause excessive current flow and possible damage to the device. >1 MΩ range resistors cause excessive thermal noise and bias currents.

Z_out for all of the amplifiers is ideally 0 Ω. Realistically, it is 1 Ω to 1 kΩ, depending on the device.

Inverting amplifier

Missing image
Opampinverting.png
Inverting Amplifier

• Inverts and amplifies a voltage (multiplies by a negative constant)
• V_out = −V_in (R_f / R_in)
• Z_in = R_in (because V₋ is a virtual ground)

Non-inverting amplifier

Missing image
Opampnoninverting.png
Non-Inverting Amplifier

• Amplifies a voltage (multipies by a constant greater than 1)
• V_out = V_in (1 + R₂ / R₁)
• Z_in = ∞ (realistically, the input impedance of the op-amp itself, 1 MΩ to 10¹² Ω)

Voltage follower

Missing image
Opampfollowing.png
Voltage Follower

• Used as a buffer, to eliminate loading effects or to interface impedances (connecting a device with a high source impedance to a device with a low input impedance)
• V_out = V_in
• Z_in = ∞ (realistically, the input impedance of the op-amp itself, 1 MΩ to 10¹² Ω)

Difference amplifier

• For independent R₁,R₂,R₃,R₄ (differential amplifier):
  • <math> V_{out} = V_2 \left( { \left( R_3 + R_1 \right) R_4 \over \left( R_4 + R_2 \right) R_1} \right) - V_1 \left( {R_3 \over R_1} \right) <math>
• For R₁ = R₂ and R₃ = R₄ (amplified difference),
  • <math> V_{out} = {R_3 \over R_1} \left( V_2 - V_1 \right) <math>
• For R₁ = R₃ and R₂ = R₄ (also for R₁ = R₂ = R₃ = R₄) (difference amplifier):
  • <math> V_{out} = V_2 - V_1 \,\!<math>
• Differential Z_in (between the two input pins) = R₁ + R₂
• An instrumentation amplifier is made by adding a voltage follower to each input to increase the input impedance.

Summing amplifier

• Sums several (weighted) voltages
• Output is inverted
• For independent R₁, R₂, ... R_n
  • V = − R_f (V₁ / R₁ + V₂ / R₂ + ... + V_n / R_n)
• For R₁ = R₂ = ... = R_n, and R_F independent
  • V = − (R_f / R₁) (V₁ + V₂ + ... + V_n)
• For R₁ = R₂ = ... = R_n = R_f
  • V = − (V₁ + V₂ + ... + V_n)
• Input impedance Z_n = R_n, for each input (V₋ is a virtual ground)

Integrator

• Integrates the signal over time (where V_in and V_out are functions of time)
• <math> V_{out} = \int_0^t - {V_{in} \over RC} \, dt + V_{initial} <math>
  (V_initial is the output voltage of the integrator at time t = 0.)
• Note that this can also be viewed as a type of electronic filter.

Differentiator

Missing image
Opampdifferentiating.png
Differentiating Amplifier

• Differentiates the signal over time (where V_in and V_out are functions of time)
• <math> V_{out} = - R C \, {d V_{in} \over dt} <math>
• Note that this can also be viewed as a type of electronic filter.

Comparator

Missing image
Opampcomparator.png
Comparator

• Compares two voltages and outputs one of two states depending on which is greater
• <math> V_{out} = \left\{\begin{matrix} V_{S+} & V_1 > V_2 \\ V_{S-} & V_1 < V_2 \end{matrix}\right. <math>
• See article for details

Schmitt trigger

• A comparator with hysteresis
• See article for details

Inductance gyrator

• Simulates an inductor
• See article for details