FOURIER SERIES Jean-Baptiste Fourier (France, 1768 - 1830 - PowerPoint PPT Presentation

1 / 11
About This Presentation
Title:

FOURIER SERIES Jean-Baptiste Fourier (France, 1768 - 1830

Description:

FOURIER SERIES Jean-Baptiste Fourier (France, 1768 - 1830) proved that almost any period function can be represented as the sum of sinusoids with integrally related ... – PowerPoint PPT presentation

Number of Views:132
Avg rating:3.0/5.0
Slides: 12
Provided by: eeUiAcId
Category:

less

Transcript and Presenter's Notes

Title: FOURIER SERIES Jean-Baptiste Fourier (France, 1768 - 1830


1
FOURIER SERIES
  • Jean-Baptiste Fourier (France, 1768 - 1830)
    proved that almost any period function can be
    represented as the sum of sinusoids with
    integrally related frequencies.
  • The Fourier series is one example of an
    orthogonal set of basis functions, as a very
    important example for engineers.
  • Trigonometric form of Fourier Series
  • Let us map the functions 1, and by the
    following
  • The purpose of this nothing deeper than to map
    the conventional Fourier series onto the notation
    we have derived for orthogonal functions

2
  • The Fourier series is a special case of the more
    general theory of orthogonal functions.
  • Now calculate the value of lm from
  • ie
  • The value of lm for is simply the
    power in a sinewave (cosine wave)
  • The value of l0 is the power in a DC signal of
    unit amplitude.
  • Now we can derive immediately the Euler formula
    from equation
  • by substituting in the values of and lm from
    the above equations then

3
  • In the Fourier series, instead of using the term
    a-m as the coefficient of the cosine terms in the
    Fourier expansion we usually use the term am with
    bm reserved for the sine terms.
  • The important point to realize here is that the
    Fourier series expansion is only a special case
    of an expansion in terms of orthogonal functions
  • There are many other function (e.g. Walsh
    function), so using the Fourier series as an
    example, try and understand the more general
    orthogonal function approach
  • When we write a periodic function using a Fourier
    series expansion in terms of a DC term and sine
    and cosine terms the problem which remains is to
    determine the coefficients a0 , am and bm

4
  • Solving a problem using Fourier series
  • Consider a sawtooth wave which rises from -2V to
    2V in a second. It passes through a linear time
    invariant communication channel which does not
    pass frequencies greater than 5.5 Hz.
  • What is the power lost in the channel ? Assume
    the output and input impedance are the same. (Use
    sine or cosine Fourier series).

5
  • The first step is set up the problem
    mathematically.
  • The time origin has not been specified in the
    problem.
  • Since the system is time invariant it doesn't
    matter when t 0 is located since it is will not
    change the form of the output.
  • Choose time t 0 at the center of the rise of
    the sawtooth because it makes the function which
    we now call u(t), into an odd function.
  • Since the system is specified in terms of it
    frequency response, i.e. what it will do if a
    sinwave of a given frequency is input, it makes a
    lot of sense to express as a sum of either sines
    and cosines or complex exponentials since as we
    know what happens to these functions.
  • If it's a sinewave or cosine wave and has a
    frequency less than 5.5 Hz it is transmitted,
    otherwise it is eliminated.
  • The situation with complex exponential is a
    little trickier, if its in the range -5.5,5.5
    Hz then will be transmitted otherwise will be
    eliminated.
  • It would do no good to find the response to each
    sinewave individually, because we could not then
    add up these individual response to form the
    total output, because that would require
    superposition to hold.

6
  • Let us calculate the Fourier series for a
    sawtooth wave or arbitrary period and amplitude.
    Now with the choice of t 0, we can write the
    input as mathematically within the period as
  • We don't need to worry that outside the range
    -T/2 lt t lt T/2 the above formula is incorrect
    since all the calculation are done within the
    range -T/2 lt t lt T/2.
  • As we strict to the range given the mathematical
    description is identical to the sawtooth and all
    will be well.
  • We want the input to written in the form

7
  • Go back to Euler formula for Fourier series which
    have derived earlier from the general
    orthogonality conditions
  • Now for the DC value of the sawtooth
  • For an the coefficients of the cosine terms

8
  • The next step is use integration by parts, i.e.
  • Therefore

9
  • This is a lot of work for 0, when it is fairly
    obvious that the integral of the product of an
    odd function (sawtooth) and an even function (the
    cosine term) is always zero when we integrate
    from -v,v whatever value of v, as shown below
  • The procedure for calculating for is almost
    identical, the final answer is
  • Now we know a0 , an and bn , we can write down
    the Fourier series representation for u(t) after
    substituting T 1 and A 2
  • The series has all the sine terms present, i.e.bm
    is never zero and there are no cosine terms.

10
  • How can be check that our calculations for u(t)
    is correct ?
  • We can calculate the power in the signal by
  • and also by Parseval's theorem when applied to
    sine and cosine functions
  • Where the 0.5 came from ?
  • Remember that is lm which has the basis function
    was equal to sin(t) and the power in the
    sinewave, lm 0.5 .
  • Having calculated the Fourier series and having
    checked it using the Parseval's theorem it only
    remains to calculate the power in the first 5
    harmonics, i.e. those with a frequency less than
    5.5 Hz

11
  • Thus the power transmitted by the channel is
  • The power loss is therefore 1.3333 - 1.1863
    0.1470, and the power gain in dB is thus -0.51
    dB.
  • The final answer is that the channel attenuates
    the signal by 0.51 dB.
Write a Comment
User Comments (0)
About PowerShow.com