System analysis

See also systems analysis.

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System analysis is the branch of electrical engineering that characterizes electrical systems and their properties. Although many of the methods of system analysis can be applied to non-electrical systems, it is a subject often studied by electrical engineers because it has direct relevance to many other areas of their discipline, most notably signal processing and communication systems.

Characterization of systems

A system is characterized by how it responds to input signals. In general, a system has one or more input signals and one or more output signals. Therefore, one natural characterization of systems is by how many inputs and outputs they have:

• SISO (Single Input, Single Output)
• SIMO (Single Input, Multiple Outputs)
• MISO (Multiple Inputs, Single Output)
• MIMO (Multiple Inputs, Multiple Outputs)

It is often useful (or necessary) to break up a system into smaller pieces for analysis. Therefore, we can regard a SIMO system as multiple SISO systems (one for each output), and similarly for a MIMO system. By far, the greatest amount of work in system analysis has been with SISO systems, although many parts inside SISO systems have multiple inputs (such as adders).

Signals can be continuous or discrete in time, as well as continuous or discrete in the values they take at any given time:

• Signals that are continuous in time and continuous in value are known as analog signals.
• Signals that are discrete in time and discrete in value are known as digital signals.
• Signals that are discrete in time and continuous in value are called discrete-time signals. While important mathematically, systems that process discrete time signals are difficult to physically realize. The methods developed for analyzing discrete time signals and systems are usually applied to digital signals and systems.
• Signals that are continuous in time and discrete in value are sometimes seen in the timing analysis of logic circuits, but have little to no use in system analysis.

With this categorization of signals, a system can then be characterized as to which type of signals it deals with:

• A system that has analog input and analog output is known as an analog system.
• A system that has digital input and digital output is known as a digital system.
• Systems with analog input and digital output or digital input and analog output are possible. However, it is usually easiest to break these systems up for analysis into their analog and digital parts, as well as the necessary analog to digital or digital to analog converter.

Another way to characterize systems is by whether their output at any given time depends only on the input at that time or perhaps on the input at some time in the past (or in the future!).

• Memoryless systems do not depend on any past input.
• Systems with memory do depend on past input.
• Causal systems do not depend on any future input.
• Non-causal or anticipatory systems do depend on future input. Note: It is not possible to physically realize a non-causal system. However, from the standpoint of analysis, they are important for two reasons. First, the ideal system for a given application is often a noncausal system, which although not physically possible can give insight into the design of a causal system to accomplish a similar purpose. Second, there are instances when a system does not operate in "real time" but is rather simulated "off-line" by a computer.

Analog systems with memory may be further classified as lumped or distributed. The difference can be explained by considering the meaning of memory in a system. Future output of a system with memory depends on future input and a number of state variables, such as values of the input or output at various times in the past. If the number of state variables necessary to describe future output is finite, the system is lumped; if it is infinite, the system is distributed.

Finally, systems may be characterized by certain properties which facilitate their analysis:

• A system is linear if it has the superposition and scaling properties.
• A system that is not linear is non-linear.
• If the output of a system does not depend explicitly on time, the system is said to be time-invariant; otherwise it is time-variant
• A system that will always produce the same output for a given input is said to be deterministic.
• A system that will produce different outputs for a given input is said to be stochastic.

There are many methods of analysis developed specifically for linear time-invariant (LTI) deterministic systems. Unfortunately, in the case of analog systems, none of these properties are ever perfectly achieved. Linearity implies that operation of a system can be scaled to arbitrarily large magnitudes, which is not possible. Time-invariance is violated by aging effects that can change the outputs of analog systems over time (usually years or even decades). Thermal noise and other random phenomena ensure that the operation of any analog system will have some degree of stochastic behavior. Despite these limitations, however, it is usually reasonable to assume that deviations from these ideals will be small.

LTI Systems

As mentioned above, there are many methods of analysis developed specifically for LTI systems. This is due to their simplicity of specification. An LTI system is completely specified by its transfer function (which is a rational function for digital and lumped analog LTI systems). Alternatively, we can think of an LTI system being completely specified by its frequency response. A third way to specify an LTI system is by its characteristic linear differential equation (for analog systems) or linear difference equation (for digital systems). Which description is most useful depends on the application.

The distinction between lumped and distributed LTI systems is important. A lumped LTI system is specified by a finite number of parameters, be it the zeros and poles of its transfer function, or the coefficients of its differential equation, whereas specification of a distributed LTI system requires a complete functional description of its transfer function. The number of parameters needed to specify a lumped system is known as its order, so a distributed system can be thought of as system of infinite order. While distributed LTI systems do exist, they are not as extensively studied because:

• a distributed system can usually be approximated quite well by a lumped system of sufficient order
• distributed systems are not designed in the same manner as lumped systems, that is, by building up the transfer function from first and second-order stages

These considerations are important in digital filter design.

Engineers often look at the poles and zeros of an LTI system in the complex plane, where it is easy to determine stability properties.

See also

Important concepts in system analysis:

• Transfer function
• LTI system theory
• Feedback and stability
• Frequency response
• Steady-state and transient behavior
• Filters
• Noise (physics)
• Transforms
  • Fourier transform: Continuous Fourier transform & Discrete Fourier transform
  • Laplace transform
  • Z-transform
• Information theory

Related fields:

• Control system and control theory
• Digital signal processing
• Digital image processing
• Telecommunications