Description
Course Name: CERTIFICATE IN ADVANCE COMMUNICATION
Course Id: CAC/Q1001.
Education Qualification: 10th Pass.
Duration: 90 Hrs.
How You will Get Diploma Certificate:
Step 1- Select your Course for Certification.
Step 2- Click on Enroll Now.
Step 3- Proceed to Enroll Now.
Step 4- Fill Your Billing Details and Proceed to Pay.
Step 5- You Will be Redirected to Payment Gateway, Pay Course and Exam Fee by Following Options.
Card(Debit/Credit), Wallet, Paytm, Net banking, UPI and Google pay.
Step 6- After Payment You will receive Study Material on your email id.
Step 7- After Completion of Course Study give Online Examination.
Step 8- After Online Examination you will get Diploma Certificate soft copy(Scan Copy) and Hard Copy(Original With Seal and Sign).
Step 9- After Certification you will receive Prospect Job Opportunities as per your Interest Area.
Online Examination Detail:
Duration- 60 minutes.
No. of Questions- 30. (Multiple Choice Questions).
Maximum Marks- 100, Passing Marks- 40%.
There is no negative marking in this module.
Benefits of Certification:
- Government Authorized Assessment Agency Certification.
- Certificate Valid for Lifetime.
- Lifetime Verification of Certificate.
- Free Job Assistance as per your Interest Area.
Syllabus
Certificate in Advance Communication
APPLIED MATHEMATICS FOR ELECTRONICS AND COMMUNICATION ENGINEERS
ADVANCED RADIATION SYSTEMS
ADVANCED DIGITAL COMMUNICATION TECHNIQUES
ADVANCED DIGITAL SIGNAL PROCESSING
OPTICAL COMMUNICATION NETWORKS
WIRELESS MOBILE COMMUNICATION
APPLIED MATHEMATICS FOR ELECTRONICS AND COMMUNICATION ENGINEERS
Spaces of vectors- Null space- Rank – Row reduced form – Independence – Basis – Dimension – Four fundamental subspaces – Linear transformations – Matrix of linear transformation – Orthogonality of vectors – Orthogonal subspace – Projections – Orthogonal bases, Advanced Matrix Theory: Some important matrix factorization: LU factorization –The Cholesky Decomposition- QR factorization – Singular value decomposition -Pseudo inverse – Least square approximations – Toeplitz matrices and some applications, Numerical Solution of Differential Equations: Initial Value Problems – Single step methods: Picard’s method – Taylor’s series –Runge-Kutta method of fourth order – Numerical stability of Runge-Kutta method – Adams – Bashforth multistep method – Shooting method for linear differential equations – Boundary Value Problem – Finite difference method for linear differential equations – Laplace equation, Basic Terminologies- Constructing a project network- Network computations in CPM and PERT- Cost crashingResource leveling.
ADVANCED RADIATION SYSTEMS
Antenna fundamental parameters, Radiation integrals, Radiation from surface and line current distributions – Introduction to numerical techniques- FEM, FDTD, MoM, Linear array –uniform array, end fire and broad side array, gain, beam width, side lobe level- Two dimensional uniform array- Phased array, beam scanning, grating lobe, feed network- Linear array synthesis techniques – Binomial and Chebyshev distributions, RADIATION FROM APERTURES: Field equivalence principle, Radiation from Rectangular and Circular apertures, Uniform aperturedistribution on an infinite ground plane; Slot antenna; Horn antenna-Reflector antenna, aperture blockage, and design consideration, MICRO STRIP ANTENNA: Radiation Mechanism from patch- Excitation techniques; Microstrip dipole; Rectangular patch, Circular patch, and Ring antenna – radiation analysis from cavity model- input impedance of rectangular and circular patch antennaMicrostrip array and feed network- Application of microstrip array antenna, SPECIAL ANTENNAS: Need of metamaterial structures, Advantages of metamaterial structures, Design of the metamaterial antennas, Fractal antennas, polarization sensitive antenna design, sinuous antennas, EBG structure, PBG structures, CNT antennas.
ADVANCED DIGITAL COMMUNICATION TECHNIQUES
DETECTION: Pass band Transmission model – Gram Schmidt orthogonalization procedure, Geometric Interpretation of signals, Response of bank of correlators to a noisy input-Detection of Known signals in noise – correlation Receiver- Matched Filter Receiver – Detection of signals with unknown phase- Probability of error, Constant Envelope Modulation: Advantages of Constant Envelope Modulation – Minimum Shift Keying- Gaussian Minimum Shift Keying- M-ary Pulse Amplitude Modulation – M-ary Quadrature Amplitude Modulation – M-ary Phase Shift Keying- M-ary Frequency Shift Keying, Non Coherent modulation Techniques, Convolutional Coding: Representation of codes using Polynomial- State diagram- Tree diagram- and Trellis diagram – Maximum likelihood Decoding – Distance properties – Sequential decoding. Coded modulation for bandwidth-constrained.
ADVANCED DIGITAL SIGNAL PROCESSING
DISCRETE RANDOM SIGNAL PROCESSING: Discrete Random Processes- Ensemble Averages, Stationary processes, Bias and Estimation, Auto covariance, Autocorrelation, Parseval’s theorem, Wiener-Khintchine relation, White noise, Power Spectral Density, Spectral factorization, Filtering Random Processes, Special types of Random Processes – ARMA, AR, MA – Yule- Walker equations, Spectral Estimation: Estimation of spectra from finite duration signals, Nonparametric methods – Periodogram, Modified periodogram, Bartlett, Welch and Blackman-Tukey methods, Parametric methods – ARMA, AR and MA model based spectral estimation, Solution using Levinson-Durbin algorithm, Linear prediction – Forward and Backward prediction, Solution of Prony’s normal equations, Least mean-squared error criterion, Wiener filter for filtering and prediction, FIR and IIR Wiener filters, Discrete Kalman filter, FIR adaptive filters – adaptive filter based on steepest descent method- Widrow-Hoff LMS algorithm, Normalized LMS algorithm, Adaptive channel equalization, Adaptive echo cancellation, Adaptive noise cancellation, RLS adaptive algorithm.
OPTICAL COMMUNICATION NETWORKS
Light propagation in optical fibers – Loss & bandwidth, Dispersion effects, Non-Linear effects; Solitons- Optical Network Components – Couplers, Isolators & Circulators, Multiplexers & Filters, Optical Amplifiers, Switches, Wavelength Converters. Unit II Optical Network, Optical Network Architecture: Introduction to Optical Networks: SONET / SDH standards, Metro politon Area Networks, Layered Architecture Broadcast and Select Networks– Topologies for Broadcast Networks, Media Access Control Protocols, Test beds for WDM; Outline of Wavelength Routing Architecture, Wavelength Routing Network: Optical layer, Node Designs, Routing and Wavelength Assignment, Virtual topology design problem, Regular virtual topology design- Predetermined Virtual topology and Light path routes-Architectural variations, Photonic Packet Switching – OTDM, Multiplexing and De multiplexing, Synchronisation, Broadcast OTDM networks, Switch-based networks- Access Networks – Network Architecture overview.
WIRELESS MOBILE COMMUNICATION
Overview of wireless systems – Physical modeling for wireless channels – Time and Frequency coherence – Statistical channel models – Capacity of wireless Channel – Capacity of Flat Fading Channel – Channel Distribution Information known – Channel Side Information at Receiver – Channel Side Information at Transmitter and Receiver – Capacity with Receiver diversity – Capacity comparisons – Capacity of Frequency Selective Fading channels, Narrowband MIMO model – parallel decomposition of the MIMO channel – MIMO channel capacity – MIMO diversity gain: Beam forming – Space time modulation and coding – Frequency selective MIMO channels, Data Transmission using Multiple Carriers – Multicarrier Modulation with Overlapping Sub channels – Mitigation of Subcarrier Fading – Discrete Implementation of Multicarrier Modulation – Peak to average Power Ratio- Frequency and Timing offset, Challenges of IP Mobility -Address Management – Dynamic Host Configuration Protocol and Domain Name Server Interfaces – Security – Mobility-Based AAA Protocol – IP Mobility Architecture Framework – x Access Network – IPv6 Challenges for IP Mobility.