TUTORIAL ON HARMONICS Theory and Computation Techniques C.J. Hatziadoniu:
AC Drive Harmonics Harmonic Sources: Power converter switching action Motor own generated harmonics (spatial distribution of windings, stator saturation) Transformer/inductor iron core saturation Harmonics flowing between generator and motor sides
Potential Problems due to Harmonics Power losses and heating: reduced efficiency, equipment de-rating Over-voltage and voltage spiking, due to resonance: insulation stressing, limiting the forward and reverse blocking voltage of power semiconductor devices, heating, de-rating EMI: noise, control inaccuracy or instability Torque pulsation: mechanical fatigue, start-up limitation
Power Loss and Heating Losses into the resistive and magnetic components Resistive losses: skin effect Magnetic losses: Eddy currents and hysterisis losses increase with frequency
Over-Voltage, Over-Current (due to resonance) Capacitor loss due to harmonics (insulation loss)
Interference with Control, EMI
What Are Harmonics? Technical Description A high frequency sinusoidal current or voltage produced by certain non-linear and switching processes in the system during normal periodic operation (steady state); The harmonic frequency is an integer multiple of the system operating frequency (fundamental). The non-sinusoidal part in a periodic voltage or current is the harmonic ripple or harmonic distortion—comprised of harmonic frequencies. Mathematical Definition Sine and cosine functions of time with frequencies that are integer multiples of a fundamental frequency Harmonic sine and cosine functions sum up to a periodic (non- sinusoidal) function Terms of the Fourier series expansion of a periodic function;
Harmonic Analysis What is it? Principles, properties and methods for expressing periodic functions as sum of (harmonic) sine and cosine terms: Fourier Series Fourier Transform Discrete Fourier Transform Where is it used? Obtain the response of a system to arbitrary periodic inputs; quantify/assess harmonic effects at each frequency Framework for describing the quality of the system input and output signals (spectrum)
Superposition A LTI system responds linearly to its inputs i1 o1, i2 o2 a i1 +b i2 a o1 +b o2 For sinusoidal inputs:
Application preview: DC Drive Find the armature current i o (t) below
DC Voltage Approximation
Source Superposition
Output Response
Procedure to obtain response Step 1: Obtain the harmonic composition of the input (Fourier Analysis) Step 2: Obtain the system output at each input frequency (equivalent circuit, T.F. frequency response) Step 3: Sum the outputs from Step 2.
Fundamental Theory Outline Harmonic Fundamental Theory—Part a: Periodic Signals—sinusoidal function approximation Fourier Series—definition, computation Forms of the Fourier Series Signal Spectrum Applications of the FS in LTI Wave Form Quality of Periodic Signals
Measures Describing the Magnitude of a Signal Amplitude and Peak Value Average Value or dc Offset Root Mean Square Value (RMS) or Power
Amplitude and Peak Value Peak of a Symmetric Oscillation
Non-Symmetric Signals Peak-to-peak variation
Average Value Signal=(constant part) + (oscillating terms)
Examples
AC Signals Zero Average Value
DC and Unidirectional Signals
Root Mean Square Value (RMS) For periodic signals, time window equals one period
Remarks on RMS RMS is a measure of the overall magnitude of the signal (also referred to as norm or power of the signal). The rms of current and voltage is directly related to power. Electric equipment rating and size is given in voltage and current rms values.
Examples of Signal RMS
Effect of DC Offset New RMS= SQRT [ (RMS of Unshifted) 2 +(DC offset) 2 ]
Examples of Signals with equal RMS
RMS and Amplitude Amplitude: Local effects in time; Device insulation, voltage withstand break down, hot spots RMS: Sustained effects in time; Heat dissipation, power output
Harmonic Analysis: Problem Statement Approximate the square pulse function by a sinusoidal function in the interval [–T/2, T/2]
General Problem Find a cosine function of period T that best fits a given function f(t) in the interval [0,T] Assumptions: f(t) is periodic of period T
Approximation Error Error: Method: Find value of A that gives the Least Mean Square Error Objective: Minimize the error e(t)
Define the average square error as : E is a quadratic function of A. The optimum choice of A is the one minimizing E. Procedure
Optimum Value of A Set dE/dA equal to zero Find dE/dA:
EXAMPLE: SQUARE PULSE
A geometrical interpretation Norm of a function, error, etc is defined as:
Shifted Pulse
Average Square Error : Approximation with many harmonic terms
Harmonic Basis The terms From an orthogonal basis Orthogonality property:
Optimum coefficients The property of orthogonality eliminates the cross harmonic product terms from the Sq. error For each n, set
Optimum coefficients Obtain the optimum expansion coefficients:
Example—Square Wave Pulse
nAB 1 4/ /3 /5 n ±4/n 0
Waveform Recovery n=1 n=1-3n=1-5n=1-7n=1-9
Example: Sawtooth
Odd Symmetry
nAnAn BnBn / 20 -1/ 30 2/3 40 -1/2 50 2/5 60 -1/3 70 2/7 n0
Periodic Approximation
Approximation of the Rectified sine A periodic signal= (constant part)+ (oscillating part)
Average Value
Harmonic Terms
Summary
Numerical Problem: DC Drive
Input Harmonic Approximation Average or dc component Harmonic Expansion Truncated Approximation (n=2, 4, and 6)
Equivalent Circuit
Superimpose Sources: DC Source
Superposition: n=2, f=120 Hz
Superposition: n=4, f=240 Hz
Superposition: n=6, f=360 Hz
Summary Freq., Hz V o ampl, VI o ampl, A Z a magn, Power loss, W 0 (dc) , RMS Total Power Loss 5,057.7 Output Power (66.1A)(150V) 9,915
Output Time and Frequency Response
Generalization: Fourier Series The Fourier theorem states that a bounded periodic function f(t) with limited finite number of discontinuities can be described by an infinite series of sine and cosine terms of frequency that is the integer multiple of the fundamental frequency of f(t): Where is the zero frequency or average value of f(t).
Waveform Symmetry Half Wave Symmetry Quarter Wave Symmetry Odd Even
Half Wave Symmetry Half-wave symmetry is independent of the function shift w.r.t the time axis Even harmonics have zero coefficient
Square Wave
Triangular
Saw Tooth—Counter Example
Quarter Wave Symmetry Half wave and odd symmetry Half wave and even symmetry
Half-wave: odd and even
Quarter Wave Symmetry Simplification
Forms of the Fourier Transform Trigonometric Combined Trigonometric Exponential
Trigonometric form Combined Trigonometric
Exponential
Relations between the different forms of the FS
Summary of FS Formulas
Time Shift
Example: SQP -90° Shift originalshifted n2|C n | nn n 1 4/ 0 /3 /5 0 /7 n 4/n (n-1) /2- /2
Example: SQP -60° Shift originalshifted n2|C n | nn n 1 4/ 0 /3 /5 0 /7 n 4/n (n-1) /2(n-3) /6
SPECTRUM: SQ. Pulse (amplitude=1)
SPECTRUM: Sawtooth (amplitude=1)
SPECTRUM: Triangular wave (amplitude=1)
SPECTRUM: Rectified SINE (peak=1)
Using FS to Find the Steady State Response of an LTI System Input periodic, fundamental freq.=f 1 =60 Hz Voltage Division
Square Pulse Excitation Harm. Order Circ. TF |H(n)|, <H(n) Inp. |Uin(n)|, <Uin(n) Out. |Uout(n)|, <Uout(n)
SQUARE PULSE Excitation
Rectified SINE Wave Harm. Order Circ. TF |H(n)|, <H(n) Inp. |Uin(n)|, <Uin(n) Out. |Uout(n)|, <Uout(n)
Rect. SINE wave
Total RMS of A Signal Rewrite the FS as: Nth harmonic rms (except for n=0) Total rms of the wave form:
Total RMS and the FS Terms For ac wave forms (A 0 =0) it is convenient to write: Using the orthogonality between the terms:
Waveform Quality-AC Signals Total Harmonic Distortion Index
Waveform Quality-DC SIgnals (A 0 ≠0) Ripple Factor
Example: W.F.Q. of the circuit driven by a Sq.P. Harm. Order Inp. Rms: |Uin(n)|/√2 Out. Rms: |Uout(n)|/√ RMS 1.00 (excact) %THD (exact) 13.6 √( – )= {
Example: WFQ of the circuit driven by a rect. sine Harm. Order Inp. Rms: |Uin(n)|/√2 Out. Rms: |Uout(n)|/√ =U in (0)0.6366=U out (0) E E RMS (exact) %RF (exact) 2.5