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CELLULAR COMMUNICATIONS MIDTERM REVIEW
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Representing Oscillations w is angular frequency Need two variables to represent a state Use a single 2D variable to represent a state as a vector (a phasor)
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Wavelength and propagation velocity
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Constructive and Destructive Interference
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Doppler Effect When no relative motion When moving @U
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Fast fading: Multipath
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ISI
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Example
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Example: Sawtooth Frequency Domain X(k)=1/k
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Ambiguity problem
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Ambiguity in frequency domain
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Nyquist sampling frequency Signal band Avoid aliasing Nyquist sampling frequency Maximum frequency without aliasing
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Time vs. Frequency Short pulse in time domain->wide spectrum
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Power Spectral Density(PSD)
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Example:1Hz+3Hz
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Nonlinear Example: 1Hz+3Hz f(x1+x2)!=f(x1)+f(x2)
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SUI are a basis
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Finite Impulse Response Filter Impulse response
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Convolution
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Convolution in Frequency Domain x(t), y(t) are signals X(f), Y(f) are their spectrum What is the spectrum C(f) of Convolution theorem C=X*Y (multiplication) Convolution in the time domain===Multiplication in the frequency domain
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Amplitude Modulation(AM) Change amplitude of the signal according to information Simplest digital form is “on-off keying”(telegraph Morse code)
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Audio AM
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Frequency Modulation
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Phase Modulation Another form of FM
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Circular 16-QAM
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Frequency Hopping
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Example :DSSS with PN Transmitter/Receiver should be able to generate same synchronized Pseudo Random Noise sequences
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OFDM Select orthogonal carriers Reach maximum at different times Can pack close without much interference More carriers within the same bandwidth
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Hierarchy of speech coders
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-Law
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Vector quantization Encode a segment of sampled analog signal (e.g. L samples) Use codebooks of n vectors Segment all possible samples of dimension L into areas of equal probability Very efficient at very low rates( R=0.5 bits per sample)
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DPCM and prediction
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Sub-band coding Human ear does not detect error at all frequencies equally well
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Human Vocal Tract demo
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Voice Generation Model
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LPC
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Mean Opinion Score Quality Rating
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Codec MOS rating
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Binary Symmetric Channel Transmission medium introduce errors Demodulator produces errors Model as a channel Memoryless: probability of error is independent from one symbol to the next Symmetric: any error is equally probable Binary Symmetric Channel (BSC)
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Error Correcting Codes (ECC) Redundancy added to information Encode message of k bits with n (n>k) bits Example: Systematic Encoding Redundant symbols are appending to information symbols to obtain a coded sequence Codeword
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Error correction vs. Error Detection Error-detection Detect that received sequence contains an error Request retransmission ARQ: Automatic Repeat Request/Query (HSDPA) Error-correction Detect that received sequence contains an error Correct the error Forward Error Correction “A Code allows correction of up to p errors and detection up to q (q>p) errors”
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Block Codes vs. Convolution Codes Block Codes Encode information block by block Each block encoded independently Encoding/Decoding is a memoryless operation Convolutional Codes Next symbol depend on a history of inputs/outputs
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Linear Codes Linear combination of valid codewords is also a codeword Code distance is a minimum among all nonzero codeword weights (number of 1s) Linear space spanned by basis:
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Syndrome Syndrome depends only on error pattern Different errors=>different syndromes except for the addition of codeword Can identify error patterns of weight w<=t by looking at the syndrome One-to-one between syndromes and errors w<=t
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Convolution Codes
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Decoding: Viterbi Algorithm Errors on the channel Find path with minimal total errors
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Trellis Coded Modulation (TCM) Combined coding and modulation scheme Make most similar signals (phases) represent most different/distance codewords
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Turbo Codes Use 2 convolutional codes on the same data Feed data in different order to the encoders
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