Is My Circuit Linear? A Definition and Guidelines for Identifying Linearity

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SUMMARY

This discussion focuses on the definition and identification of linear circuits, emphasizing that a circuit is linear if it satisfies the equation f(ax1 + bx2) = af(x1) + bf(x2). Techniques such as homogeneity and superposition are applicable only to linear circuits. The conversation highlights that while resistors (R) and capacitors (C) can be modeled linearly, real-world components like transistors and diodes often exhibit non-linear behavior. Photodiodes are noted for their exceptional linearity across a wide range of intensities.

PREREQUISITES
  • Understanding of circuit theory fundamentals
  • Familiarity with linearity concepts in electrical engineering
  • Knowledge of component characteristics, particularly for resistors, capacitors, and diodes
  • Basic grasp of superposition and homogeneity principles
NEXT STEPS
  • Study the characteristics of linear and non-linear components in circuits
  • Learn about the application of superposition in circuit analysis
  • Explore the linear approximation methods for transistors
  • Investigate the i-V characteristics of various semiconductor devices
USEFUL FOR

Electrical engineering students, circuit designers, and anyone interested in understanding the principles of linearity in electronic circuits.

wilsonb
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Homework Statement


In the Lectures, we are told that techniques like homogeneity and superposition work only for linear circuits, but in Chapter 3 of the Textbook (which is the only place I can find one) I see a definition of linearity as "A circuit is linear if and only if



Homework Equations


f(ax1 + bx2) = af(x1) + bf(x2)"

i.e. if homogeneity and superposition work for it.



The Attempt at a Solution


How do I tell, when confronted with an arbitrary circuit, whether or not it is linear - whether or not homogeneity and superposition are going to work for it?
 
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No circuit is purely linear. Even R's and C's have voltage-varying i-V characteristics. Obviously, a linear model works very well in almost all instances.

Transistor circuits are less linear: usually a linear approximation is made, like an equivalent circuit, constant beta, zero di/dVce in the linear mode, etc.

Diodes are clearly non-linear, since they conduct in one direction but not the other. Zeners are in the same category: their i-V relationships are highly non-linear.

Photodiodes are amazingly linear, providing nearly constant di/dI over as many as 5 orders of magnitude (100,000 to 1). I = intensity.

Got any other devices in mind?
 
This apply only with LINEAR ELEMENTS in circuit. In fact, only independent sources, linear-dependent sources and resistors are allowed.
 

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