Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE) PDF Download

Discrete time convolution

As the name suggests the two basic properties of a LTI system are: 

1) Linearity 

A linear system (continuous or discrete time ) is a system that possesses the property of SUPERPOSITION. The principle of superposition states that the response of sum of two or more weighted inputs is the sum of the weighted responses of each of the signals. Mathematically

y[n] = S ak yk[n] = a1y1[n] + a2y2 [n] + ...... 

Superposition combines in itself the properties of ADDITIVITY and HOMOGENEITY. This is a powerful property and allows us to evaluate the response for an arbitrary input, if it can be expressed as a sum of functions whose responses are known.

2) Time Invariance

It allows us to find the response to a function which is delayed or advanced in time; but similar in shape to a function whose response is known.

Given the response of a system to a particular input, these two properties enable us to find the response to all its delays or advances and their linear combination.

Discrete Time LTI Systems 

Consider any discrete time signal x[n]. It is intuitive to see how the signal x[n] can be represented as sum of many delayed/advanced and scaled Unit Impulse Signals

 

Mathematically, the above function can be represented as

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)
More generally any discrete time signal x[n] can be represented as

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

The above expression corresponds to the representation of any arbitrary sequence as a linear combination of shifted Unit Impulses Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE) which are scaled by x[n]. Consider for example the Unit Step function. As shown earlier it can be represented as

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

 

Now if we knew the response of a system for a Unit Impulse Function, we can obtain the response of any arbitrary input. To see why this is so, we invoke the properties of Linearity, Homogeneity ( Superposition ) and Time Invariance.

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

The left hand side can be identified as any arbitrary input, while the right hand side can be identified as the total output to the signal. The total response of the system is referred to as the CONVOLUTION SUM or superposition sum of the sequences x[n] and h[n]. The result is more concisely stated as y[n] = x[n] * h[n], where

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

Therefore, as we said earlier a LTI system is completely characterized by its response to a single signal i.e. response to the Unit Impulse signal.

Example Related to Discrete Time LTI Systems

Recall that the convolution sum is given by

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

Now we plot x[k] and h[n-k] as functions of k and not n because of the summation over k. Functions x[k] and h[k] are the same as x[n] and h[n] but plotted as functions of k. Then, the convolution sum is realized as follows 1. Invert h[k] about k=0 to obtain h[-k].

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)    Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

2. The function h[n-k] is given by h[-k] shifted to the right by n (if n is positive) and to the left (if n is negative). It may appear contradictory but think a while to verify this (note the sign of the independent variable).

In the figure below n=1

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

 

3. Multiply x[k] and h[n-k] for same coordinates on the k axis. The value obtained is the response at n i.e. Value of y[n] at a particular n the value chosen in step 2. Now we demonstrate the entire procedure taking n=0,1 thereby obtaining the response at n=0,1. The input signal x[n] and for this example is taken as :

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)
 

Case 1: For n=0

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

Remember the independence axis has k as the independent variable. Then taking the product x[k] h[-k] for same and summing it we get the value of the response at n=0.

Let h[-k] = g[k]
 y[0] = ...........x[-1]g[-1] + x[0] g[0] +............... = (-2) (1) +(1) (2) = 0 

 

Case 2: For n=1

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

 

h[1-k] =g[k] 

y[1] = .........+ x[0]g[0] + x[1]g[1] + ............. = (1)(1) +(2)(2) = 5

The values are the same as that obtained previously. The total response referred to as the Convolution sum need not always be found graphically. The formula can directly be applied if the input and the impulse response are some mathematical functions. We show this by an example next.

 

Example 

Find the total response when the input function is . Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE) And the impulse response is given by Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE) .

 

Applying the convolution formula we get

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

 

We now give an alternative method for calculating the convolution of the given signal x[n] and the response to the unit impulse function. Let us see how convolution output is the sum of weighted and shifted instances of the impulse response. Let the given signal x[n] be

 

 Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

Let the Impulse Response be

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)

Now we break the signal in its components i.e. expressed as a sum of unit impulses scaled and delayed or advanced appropriately. Simultaneously we show the output as sum of responses of unit impulses function scaled by the same multiplying factor and appropriately delayed or advanced.

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)
Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)
Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)


Summing the left and the right hand sides of the above figures we get the input x[n] and the total response on the left and the right sides respectively. Thus we see the graphical analog the above formula.

 

Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE)
 

The total response referred to as the Convolution sum need not always be found graphically. The formula can directly be applied if the input and the impulse response are some mathematical functions. We show this by a example.

 

Conclusion: 

In this lecture you have learnt:

  • The two basic properties of LTI systems are linearity and shift-invariance. It is completely characterised by its impulse response.
  • Any discrete time signal x[n] can be represented as a linear combination of shifted Unit Impulses scaled by x[n].
  • The unit step function can be represented as sum of shifted unit impulses.
  • The total response of the system is referred to as the CONVOLUTION SUM or superposition sum of the sequences x[n] and h[n]. The result is more concisely stated as y[n] = x[n] * h[n].
  • The convolution sum is realized as follows

1. Invert h[k] about k=0 to obtain h[-k]. 
2. The function h[n-k] is given by h[-k] shifted to the right by n (if n is positive) and to the left (if n is negative) (note the sign of the independent variable).
3. Multiply x[k] and h[n-k] for same coordinates on the k axis. The value obtained is the response at n i.e. Value of y[n] at a particular n the value chosen in step 2.

The document Discrete Time Convolution | Signals and Systems - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Signals and Systems.
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FAQs on Discrete Time Convolution - Signals and Systems - Electrical Engineering (EE)

1. What is discrete time convolution?
Ans. Discrete time convolution is a mathematical operation that combines two sequences to produce a third sequence. It is commonly used in signal processing and digital filtering to analyze and manipulate discrete-time signals.
2. How is discrete time convolution different from continuous time convolution?
Ans. Discrete time convolution operates on discrete-time signals, where the input and output sequences are represented by discrete samples. Continuous time convolution, on the other hand, deals with continuous-time signals, where the input and output functions are continuous. The mathematical formulas and techniques used in discrete time convolution are different from those used in continuous time convolution.
3. What is the purpose of discrete time convolution in signal processing?
Ans. Discrete time convolution plays a crucial role in signal processing as it allows us to analyze and modify signals by applying different filters and operations. It is used for tasks such as smoothing, noise reduction, frequency analysis, and system characterization. By convolving a signal with a suitable kernel, we can extract specific information or enhance certain aspects of the signal.
4. How is discrete time convolution computed?
Ans. Discrete time convolution is computed by taking the input signal and the impulse response (also known as the kernel or filter) and sliding the filter over the input signal, multiplying the corresponding samples, and summing the results. This process is repeated for each sample of the input signal to generate the output sequence. The convolution operation can be implemented using techniques like the direct method, circular convolution, or fast convolution algorithms.
5. What are some real-world applications of discrete time convolution?
Ans. Discrete time convolution finds applications in various fields, including audio and image processing, telecommunications, control systems, and biomedical signal analysis. It is used for tasks such as echo cancellation, image filtering, channel equalization, speech recognition, and system identification. Discrete time convolution provides a powerful tool for analyzing and manipulating signals in numerous practical scenarios.
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