Low Pass Filter - Electrical Engineering (EE) PDF Download

The Ideal Low-Pass Filter:
In this lecture, we examine the Ideal low pass filter and the process of reconstruction of a Band-limited signal.
Let us first see another way of interpreting the action of the Ideal low-pass filter.


IMPULSE RESPONSE OF IDEAL LOW PASS FILTER:
The Frequency response (the Fourier transform of the impulse response of an LSI system is also called its frequency response) of an ideal low pass filter which allows a bandwidth B, is a rectangle extending from -B to +B, having a constant height as shown in the figure.
 

Low Pass Filter - Electrical Engineering (EE)

Lets look at the Impulse Response of this Ideal low pass filter, taking its height in [-B, B] to be 1. Using the formula for inverse Fourier Transform we have :
 

Low Pass Filter - Electrical Engineering (EE)     Low Pass Filter - Electrical Engineering (EE)

 Thus the impulse response of an ideal low pass filter turns out to be a Sinc function, which looks like:
 

Low Pass Filter - Electrical Engineering (EE)

Reconstruction of a signal by low pass filter :

Consider a signal x(t) having bandwidth less than B.


We sample x(t) at a rate 2B and pass  Low Pass Filter - Electrical Engineering (EE)  into an Ideal low -pass filter of bandwidth B . Low Pass Filter - Electrical Engineering (EE)

 

The signal x(t) and the signal  Low Pass Filter - Electrical Engineering (EE) obtained by multiplying the signal by a periodic train of impulses, separated by T0 , having strength 1 are shown below.

 

Low Pass Filter - Electrical Engineering (EE)     Low Pass Filter - Electrical Engineering (EE)

 

What happens when Low Pass Filter - Electrical Engineering (EE) is fed into the LSI system?


Lets look at the convolution of the impulse response h(t) of the Ideal low-pass filter with  Low Pass Filter - Electrical Engineering (EE)
 

Low Pass Filter - Electrical Engineering (EE)

where we have seen

 

Low Pass Filter - Electrical Engineering (EE)

When Low Pass Filter - Electrical Engineering (EE) is passed through a Low pass filter, the output which is the reconstructed signal is nothing but the sum of copies of the impulse response h(t) shifted by integral multiples of  T0 and multiplied by the value of x(t) at the corresponding integral multiple of T0. Also observe that the h(t) is zero at all sample points (which are integral multiples of T0 ) except at zero. Thus, the reconstruction of x(t) can be visualized as a sum of the following signals :

 

Low Pass Filter - Electrical Engineering (EE)

 

Problems with the IDEAL LOW PASS FILTER

It is infinitely Non-Causal:

The impulse response of the ideal low pass filter extends to -∞ . If the impulse response is denoted by h(t) , the output signal y(t) corresponding to input signal x(t) is given by :

Low Pass Filter - Electrical Engineering (EE)

The value of y at any t depends on values of x all the way to  if + ∞ h(t) extends to -∞. Thus realization in real time is not possible for an Ideal low-pass filter. In other words, unless one knows the entire Low Pass Filter - Electrical Engineering (EE) , reconstruction cannot be done.


Note if h(t) had been finitely non-causal (say zero for all t less than some - t0), then real time realization would have been possible subject to a time-delay (of t0). 

It is unstable:

It can be shown that  Low Pass Filter - Electrical Engineering (EE) diverges.


Challenging Problem: Prove that Ideal filter is unstable.
Proof:

Low Pass Filter - Electrical Engineering (EE)

which is greater than
Low Pass Filter - Electrical Engineering (EE)
and we know that this series diverges. Hence it is established that the Ideal Low Pass Filter is unstable.
This implies that bounded input does not imply bounded output. Thus if we build an oscillator with Ideal Low pass Filter a bounded input may result in an unstable output. 

The system is not rational: 

That means, it is not exactly realizable with simple well known elements .
We will get back to how these problems are tackled a little later. In the next lecture, we move on to the problem of impulses not being physically realizable.

Conclusion:

In this lecture you have learnt:

  • Impulse response of an ideal low pass filter turns out to be a Sinc function.
  • When sampled signal is passed through a low pass filter, reconstructed output signal is nothing but the sum of copies of impulse response h(t) shifted by integral multiples of T0 and multiplied by the value of x(t) at the corresponding integral multiple of T0  .
  • Problems with the ideal low pass filter :
    1. It is infinitely non-causal.
    2. It is unstable.
    3. It is not a rational system.
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FAQs on Low Pass Filter - Electrical Engineering (EE)

1. What is a low pass filter?
Ans. A low pass filter is an electronic circuit that allows low-frequency signals to pass through while attenuating or blocking high-frequency signals. It is commonly used in audio systems to eliminate or reduce unwanted high-frequency noise and interference.
2. How does a low pass filter work?
Ans. A low pass filter works by using passive components such as resistors, capacitors, and inductors to create a frequency-dependent impedance network. This network allows low-frequency signals to pass through with minimal attenuation, while high-frequency signals experience increasing levels of attenuation. The specific cutoff frequency of the filter determines the point at which the attenuation begins.
3. What is the purpose of using a low pass filter?
Ans. The main purpose of using a low pass filter is to remove or reduce high-frequency noise and interference from a signal, allowing only the desired low-frequency components to pass through. This is particularly useful in applications such as audio systems, where it helps improve the clarity and quality of the sound by eliminating unwanted high-frequency artifacts.
4. How can a low pass filter be implemented in a circuit?
Ans. A low pass filter can be implemented in a circuit using various configurations, such as the RC (resistor-capacitor) filter, RL (resistor-inductor) filter, or the more complex active filter designs using operational amplifiers. The choice of circuit configuration depends on factors such as the desired cutoff frequency, filter response characteristics, and the available components.
5. What are the different types of low pass filters?
Ans. There are several types of low pass filters, including the Butterworth filter, Chebyshev filter, Bessel filter, and elliptic filter. These filters differ in terms of their frequency response characteristics, such as the steepness of the roll-off beyond the cutoff frequency and the presence of ripples in the passband or stopband. The choice of filter type depends on the specific requirements of the application.
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