Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter4 Bandpass Signalling Bandpass Filtering and Linear Distortion

Published byGwenda Shepherd Modified over 5 years ago

Similar presentations

Presentation on theme: "Chapter4 Bandpass Signalling Bandpass Filtering and Linear Distortion"— Presentation transcript:

1 Chapter4 Bandpass Signalling Bandpass Filtering and Linear Distortion
Amplifiers and Nonlinear Distortion Total Harmonic Distortion (THD) Intermodulation Distortion (IMD) Huseyin Bilgekul Eeng360 Communication Systems I Department of Electrical and Electronic Engineering Eastern Mediterranean University

2 Bandpass Filtering and Linear Distortion
Equivalent Low-pass filter: Modeling a bandpass filter by using an equivalent low pass filter (complex impulse response) Bandpass filter H(f) = Y(f)/X(f) Input bandpass waveform Output bandpass waveform Impulse response of the bandpass filter Frequency response of the bandpass filter

3 Bandpass Filtering

4 Bandpass Filtering Theorem:
The complex envelopes for the input, output, and impulse response of a bandpass filter are related by g1(t) – complex envelope of input k(t) – complex envelope of impulse response Also, Proof: Spectrum of the output is Spectra of bandpass waveforms are related to that of their complex enveloped But

5 Bandpass Filtering Thus, we see that
Taking inverse fourier transform on both sides Any bandpass filter may be described and analyzed by using an equivalent low-pass filter. Equations for equivalent LPF are usually much less complicated than those for bandpass filters & so the equivalent LPF system model is very useful.

6 Linear Distortion For distortionless transmission of bandpass signals, the channel transfer function H(f) should satisfy the following requirements: The amplitude response is constant A- positive constant The derivative of the phase response is constant Tg – complex envelope delay Integrating the above equation, we get

7 Linear Distortion

8 Bandpass filter delays input info by Tg , whereas the carrier by Td
Linear Distortion The channel transfer function is If the input to the bandpass channel is Then the output to the channel (considering the delay Tg due to ) is Using Phase response of a linear function of frequency Bandpass filter delays input info by Tg , whereas the carrier by Td Modulation on the carrier is delayed by Tg & carrier by Td

9 Received Signal Pulse The signal out of the transmitter
Transmission medium (Channel) Carrier circuits Signal processing Information m input The signal out of the transmitter g(t) – Complex envelope of v(t) If the channel is LTI , then received signal + noise n(t) – Noise at the receiver input Signal + noise at the receiver input A – gain of the channel - carrier phase shift caused by the channel, Tg – channel group delay. Signal + noise at the receiver input

10 Nonlinear Distortion Amplifiers Non-linear Linear
Circuits with memory and circuits with no memory Memory - Present output value ~ function of present input + previous input values - contain L & C No memory - Present output values ~ function only of its present input values. Circuits : linear + no memory – resistive ciruits linear + memory – RLC ciruits (Transfer function)

11 Nonlinear Distortion Assume no memory  Present output as a function of present input in ‘t’ domain If the amplifier is linear K- voltage gain of the amplifier In practice, amplifier output becomes saturated as the amplitude of the input signal is increased. output-to-input characteristic can be modelled as a Taylor’s expansion about vi =0 Where - output dc offset level - 1st order (linear) term - 2nd order (square law) term There will be nonlinear distortion on the output if K2,K3,… are non-zero.

12 2nd Harmonic Distortion with
Nonlinear Distortion Harmonic Distortion associated with the amplifier output is determined by Applying a single sinusoidal test tone to the amplifier input Let the input test tone be represented by To the amplifier input Then the second-order output term is 2nd Harmonic Distortion with = In general, for a single-tone input, the output will be Vn – peak value of the output at the frequency nf0 The Percentage Total Harmonic Distortion (THD) of an amplifier is defined by

13 Nonlinear Distortion Intermodulation distortion (IMD) of the amplifier is obtained by using a two-tone test signal : If the input (tone) signals are Then the second-order output term is IMD Harmonic distortion at 2f1 & 2f2 Second-order IMD is:

Download ppt "Chapter4 Bandpass Signalling Bandpass Filtering and Linear Distortion"

Similar presentations

Ch 3 Analysis and Transmission of Signals

Ch 3 Analysis and Transmission of Signals
C H A P T E R 3 ANALYSIS AND TRANSMISSION OF SIGNALS.

C H A P T E R 3 ANALYSIS AND TRANSMISSION OF SIGNALS.
Eeng 360 1 Chapter 2 Orthogonal Representation, Fourier Series and Power Spectra  Orthogonal Series Representation of Signals and Noise Orthogonal Functions.

Eeng Chapter 2 Orthogonal Representation, Fourier Series and Power Spectra  Orthogonal Series Representation of Signals and Noise Orthogonal Functions.
Chapter 1 - Introduction to Electronics Introduction Microelectronics Integrated Circuits (IC) Technology Silicon Chip Microcomputer / Microprocessor Discrete.

Chapter 1 - Introduction to Electronics Introduction Microelectronics Integrated Circuits (IC) Technology Silicon Chip Microcomputer / Microprocessor Discrete.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Outline of discussion DIRECT MODELING APPROACH 1.How small-signal variations in the.

Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Outline of discussion DIRECT MODELING APPROACH 1.How small-signal variations in the.
Chapter 5 AM, FM, and Digital Modulated Systems

Chapter 5 AM, FM, and Digital Modulated Systems
Chapter 25 Nonsinusoidal Waveforms. 2 Waveforms Used in electronics except for sinusoidal Any periodic waveform may be expressed as –Sum of a series of.

Chapter 25 Nonsinusoidal Waveforms. 2 Waveforms Used in electronics except for sinusoidal Any periodic waveform may be expressed as –Sum of a series of.
Chapter 4 Bandpass Signaling. In this chapter, we consider the situations where the information from a source is transmitted at its non-natural frequency.

Chapter 4 Bandpass Signaling. In this chapter, we consider the situations where the information from a source is transmitted at its non-natural frequency.
1 Let g(t) be periodic; period = T o. Fundamental frequency = f o = 1/ T o Hz or  o = 2  / T o rad/sec. Harmonics =n f o, n =2,3 4,... Trigonometric.

1 Let g(t) be periodic; period = T o. Fundamental frequency = f o = 1/ T o Hz or  o = 2  / T o rad/sec. Harmonics =n f o, n =2,3 4,... Trigonometric.
Chapter 2. Signals Husheng Li The University of Tennessee.

Chapter 2. Signals Husheng Li The University of Tennessee.
Chapter 14 Filter Circuits

Chapter 14 Filter Circuits
Eeng 360 1 Chapter 4 Bandpass Circuits   Limiters   Mixers, Upconverters and Downconverters   Detectors, Envelope Detector, Product Detector  

Eeng Chapter 4 Bandpass Circuits   Limiters   Mixers, Upconverters and Downconverters   Detectors, Envelope Detector, Product Detector  
Chapter 4. Angle Modulation. 4.7 Generation of FM Waves Direct Method –A sinusoidal oscillator, with one of the reactive elements in the tank circuit.

Chapter 4. Angle Modulation. 4.7 Generation of FM Waves Direct Method –A sinusoidal oscillator, with one of the reactive elements in the tank circuit.
Eeng 360 1 Chapter 5 AM, FM, and Digital Modulated Systems  Phase Modulation (PM)  Frequency Modulation (FM)  Generation of PM and FM  Spectrum of.

Eeng Chapter 5 AM, FM, and Digital Modulated Systems  Phase Modulation (PM)  Frequency Modulation (FM)  Generation of PM and FM  Spectrum of.
Eeng 360 1 Chapter4 Bandpass Signalling  Definitions  Complex Envelope Representation  Representation of Modulated Signals  Spectrum of Bandpass Signals.

Eeng Chapter4 Bandpass Signalling  Definitions  Complex Envelope Representation  Representation of Modulated Signals  Spectrum of Bandpass Signals.
ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Third Edition, by Allan R. Hambley, ©2005 Pearson Education, Inc. Chapter 11 Amplifiers: Specifications.

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Third Edition, by Allan R. Hambley, ©2005 Pearson Education, Inc. Chapter 11 Amplifiers: Specifications.
EEE 461 1 Chapter 6 Random Processes and LTI Huseyin Bilgekul EEE 461 Communication Systems II Department of Electrical and Electronic Engineering Eastern.

EEE Chapter 6 Random Processes and LTI Huseyin Bilgekul EEE 461 Communication Systems II Department of Electrical and Electronic Engineering Eastern.
Eeng360 1 Chapter 2 Fourier Transform and Spectra Topics:  Fourier transform (FT) of a waveform  Properties of Fourier Transforms  Parseval’s Theorem.

Eeng360 1 Chapter 2 Fourier Transform and Spectra Topics:  Fourier transform (FT) of a waveform  Properties of Fourier Transforms  Parseval’s Theorem.
Eeng 360 1 Chapter4 Transmitters and Receivers  Generalized Transmitters  AM PM Generation  Inphase and Quadrature Generation  Superheterodyne Receiver.

Eeng Chapter4 Transmitters and Receivers  Generalized Transmitters  AM PM Generation  Inphase and Quadrature Generation  Superheterodyne Receiver.
1 Eeng224 Chapter 10 Sinusoidal Steady State Analysis Huseyin Bilgekul Eeng224 Circuit Theory II Department of Electrical and Electronic Engineering Eastern.

1 Eeng224 Chapter 10 Sinusoidal Steady State Analysis Huseyin Bilgekul Eeng224 Circuit Theory II Department of Electrical and Electronic Engineering Eastern.

Similar presentations

Ads by Google