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Periodic Convolution and Auto-Correlation

Periodic Convolution 

We have applied the convolution theorem to convolutions involving:
(i) two aperiodic signals
(ii) one aperiodic and one periodic signal.

But, convolutions between periodic signals diverge, and hence the convolution theorem cannot be applied in this context. However a modified definition of convolution for periodic signals whose periods are rationally related is found useful. We look at this definition now. Later, we will prove a result similar to the Convolution theorem in the context of periodic signals.


Consider the following signals
 x(t) periodic with period T1 and h(t) periodic with period T2 where T1 and T2 are rationally related.
Let T1/T2 = m / n (where m and n are integers) Hence, m T2 = n T1 = T is a common period for both x(t) and h(t).
Periodic convolution or circular convolution of x(.) with h(.) is denoted by  and is defined as :

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)


Note the definition holds even if T is not the smallest common period for x(t) and h(t) due to the division by T. Thus we don't need m and n to be the smallest possible integers satisfying T/ T2 = m / n in the process of finding T.
Also, show for yourself that the periodic convolution is commutative, i.e: . Also, notice that the convolution is periodic with period T1 as well as T2. More on this later.
Fourier Transform of  Periodic Convolution and Auto Correlation - Electrical Engineering (EE)
Say x(t) is periodic with period T1 and h(t) is periodic with period T2 with T1 / T2 = m / n (where m and n are integers).
Thus m T2 = n T1 = T is a common period for the two.
We can expand x(t) and h(t) into Fourier Series with fundamental frequency    Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

 

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

If one compares the Fourier co-efficients in these expansions with those in the expansions with the original fundamental frequencies, i.e:

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Now,

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

But then, we have seen that Ck can be non-zero only when k is a multiple of n, and dk can be non-zero only when k is a multiple of m.
Their product can clearly be non-zero only when k is a multiple of m and n. Thus if p is the LCM (least common multiple) of m and n, we have:

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)
What can we make out of this?
The Fourier Transform of the circular convolution has impulses at all (common) frequencies where the Fourier transforms of x(t) and h(t) have impulses. The circular convolution therefore "picks out" common frequencies, at which the spectra of x(t) and h(t) are non-zero and the strength of the impulse at that frequency is the product of the strengths of the impulses at that frequency in the original two spectra.


This result is the equivalent of the Convolution theorem in the context of periodic convolution.

 

Parseval's Theorem 

We now obtain the result equivalent to the Parseval's theorem we have already seen in the context of periodic signals.
Let x(t) and y(t) be periodic with a common period T.

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)
Applying the Convolution theorem equivalent we have just proved on  Periodic Convolution and Auto Correlation - Electrical Engineering (EE) we get:

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

 Put t = 0, to get: Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

 

Compare this equation with the Parseval's theorem we had proved earlier.

If we take x = y, then T becomes the fundamental period of x and:

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Note the left-hand side of the above equation is the power of x(t).
Note also that the periodic convolution of Periodic Convolution and Auto Correlation - Electrical Engineering (EE) yields a periodic signal with Fourier coefficients that are the modulus square of the coefficients of x(t).

 

Another important result

If Periodic Convolution and Auto Correlation - Electrical Engineering (EE)  

 

 

Then Periodic Convolution and Auto Correlation - Electrical Engineering (EE) represents the power of y(t), where T is a period common to x(t) and h(t).

If 

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Applying the Parseval's theorem to y,
 

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

 

The Auto-correlation and the Cross-correlation.
Proceeding with our work on the Fourier transform, let us define two important functions, the Auto-correlation and the Cross-correlation.
Auto Correlation


You have seen that for a Periodic signal y(t), Periodic Convolution and Auto Correlation - Electrical Engineering (EE)  has Fourier series coefficients that the modulus square of the Fourier series coefficients of y(t).


Lets look at an equivalent situation with aperiodic signals, i.e:

Assume that: Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

then Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Notice that Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

SincePeriodic Convolution and Auto Correlation - Electrical Engineering (EE)

We have, Periodic Convolution and Auto Correlation - Electrical Engineering (EE)


Using the dual of the convolution theorem,

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

The auto-correlation of x(t), denoted by Periodic Convolution and Auto Correlation - Electrical Engineering (EE)  is defined as:
 

Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

ts Spectrum is the modulus square of the spectrum of x(t).

It can also be interpreted as the projection of x(t) on its own shifted version, shifted back by an interval ‘t'.

It can be shown that Periodic Convolution and Auto Correlation - Electrical Engineering (EE)  ( note that is nothing but the energy in the signal x(t) )

 Cross Correlation
The cross correlation between two signals x(t) and y(t) is defined as : Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

Note that the cross-correlation Rxy  is the convolution of .Periodic Convolution and Auto Correlation - Electrical Engineering (EE)


If Periodic Convolution and Auto Correlation - Electrical Engineering (EE) then using the fact that the auto-correlation integral peaks at 0 , the cross correlation peaks at .Periodic Convolution and Auto Correlation - Electrical Engineering (EE)
It may be said that cross-correlation function gives a measure of resemblance between the shifted versions of signal x(t) and y(t). Hence it is used to in Radar and Sonar applications to measure distances . In these systems, a transmitter transmits signals which on reflection from a target are received by a receiver. Thus the received signal is a time shifted version of the transmitted signal . By seeing where the cross-correlation of these two signals peaks, one can determine the time shift and hence the distance of the target.
The Fourier transform of Rxy (t)  is of-course Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

 

Conclusion: 

In this lecture you have learnt:
Periodic convolution or circular convolution of x(.) with h(.) is denoted by  and is defined as :
Periodic Convolution and Auto Correlation - Electrical Engineering (EE)  
Fourier Transform of Periodic Convolution and Auto Correlation - Electrical Engineering (EE)
Parseval's theorem in the context of periodic signals is Periodic Convolution and Auto Correlation - Electrical Engineering (EE) 


Auto correlation is defined as Periodic Convolution and Auto Correlation - Electrical Engineering (EE) 


Cross correlation is defined as Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

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FAQs on Periodic Convolution and Auto Correlation - Electrical Engineering (EE)

1. What is periodic convolution and how is it different from regular convolution?
Periodic convolution is a mathematical operation that combines two periodic functions to produce a third periodic function. It is different from regular convolution in that it assumes the input signals are periodic, meaning they repeat indefinitely. Regular convolution, on the other hand, does not assume periodicity and works with finite-length signals.
2. How is periodic convolution calculated?
To calculate periodic convolution, you can use the Discrete Fourier Transform (DFT). First, you compute the DFT of the two input periodic signals. Then, you multiply the corresponding frequency components and take the inverse DFT of the result. This will give you the periodic convolution of the two signals.
3. What is auto-correlation and how is it related to periodic convolution?
Auto-correlation is a measure of similarity between a signal and a time-delayed version of itself. It quantifies how much a signal "matches" or correlates with its shifted copies. Auto-correlation is related to periodic convolution because the auto-correlation of a signal is mathematically equivalent to the periodic convolution of the signal with its time-reversed version.
4. How is auto-correlation useful in signal processing?
Auto-correlation is widely used in signal processing for various applications. It can be used to detect periodicity in a signal, estimate the time delay between two signals, identify repeating patterns, and assess the similarity between two signals. Auto-correlation is particularly useful in fields such as audio processing, speech recognition, and image analysis.
5. Can periodic convolution and auto-correlation be computed efficiently?
Yes, both periodic convolution and auto-correlation can be computed efficiently using the Fast Fourier Transform (FFT) algorithm. The FFT allows for fast computation of the DFT and its inverse, significantly reducing the computational complexity compared to direct methods. The efficiency of FFT-based algorithms makes periodic convolution and auto-correlation feasible for real-time signal processing applications.
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