Single carrier Multicarrier OFDM
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Transcript of Single carrier Multicarrier OFDM
Single carrierMulticarrierOFDM
Single Carrier - ISI, Receiver complexity ISI, Bit rate limitation Multi-carrier - Negligible ISI, Approximately flat subchannels, Less receiver complexity - Adaptive allocation of power to each subbands OFDM - Overlapping spectra still separable at the receiver - Maximum data rate in band-limited channel - Digital implementation is possible - No need of steep bandpass filters
Need of orthogonality in time functions
Overlapping spectra
Synthesis of OFDM signals for multichannel data transmission No need of perpendicular cutoffs and linear phases
Overall data rate 2Overall baseband bandwidth, as N , where N are no. of subchannels
For transmitting filters designed for arbitrary amplitude characteristics, the received signals remain orthogonal for all phase characteristics of the transmission medium
The distances in signal space are independent of the phase characteristics of the transmitting filters and the transmitting medium
OFDM of N-data channels over one transmission medium
To eliminate ISI and ICI Orthogonality
Ai2(f) H2(f) Cos 2fkT df = 0, k = 1, 2,… i=1,2, … ,N, (1)
0
Ai(f) Aj (f) H2(f) Cos[i(f) - j(f)] . Cos 2fkT df = 0 and
0
Ai(f) Aj (f) H2(f) Sin[i(f) - j(f)] . Sin 2fkT df = 0
0 for k = 0,1,2, … i,j =1,2, … ,N, i j (2)
f1= (h + ½)fs & fi = f1+ (i-1)fs = (h + i - ½)fs, h is any +ve integer (3)
T = 1 / 2fs seconds (4)
Designing transmitter filter For given H(f),
Ai2(f)H2(f) = Ci + Qi(f) > 0, fi - fs f fi + fs
= 0 f fi-fs, f > fi + fs (5)
where Ci is an arbitrary constant and Qi(f) is a shaping function having odd symmetries about fi + (fs/2) and fi - (fs/2). i.e.
Qi[(fi+fs/2) + f] = -Qi[(fi+fs/2) - f], 0 f fs/2
Qi[(fi-fs/2) + f] = -Qi[(fi-fs/2) - f], 0 f fs/2 (6)
Furthermore, the function [Ci + Qi(f)][Ci+1 + Qi+1(f)] is an even function about fi + (fs/2). i.e.
[Ci + Qi(fi + fs/2+f)][Ci+1 + Qi+1(fi + fs/2+f)]
= [Ci + Qi(fi + fs/2-f)][Ci+1 + Qi+1(fi + fs/2-f)]
0 f fs/2 i = 1,2, … .N-1 (7) The phase characteristic i(f), i = 1,2, … N, be shaped such that –
i(f) - i+1(f) = /2 + i(f), fi f fi + fs , i = 1,2, …, N-1 (8)
where i(f) is an arbitrary phase function with odd symmetry about
fi + (fs/2)
Examples of required filter characteristics (i) Ci is same for all i (e.g. ½)
(ii) Qi(f), i = 1,2, …, N, is identically shaped, i.e.,
Qi+1(f) = Qi(f-fs), i = 1, 2, …, N-1, e.g.
Qi(f) = ½·Cos(.(f - fi)/fs), fi – fs f fi + fs, i=1,2, …,N, Ai
2(f)H2(f) = Ci + Qi(f) = ½ + ½ Cos((.(f - fi)/fs) Ai(f)H(f) = Cos((.(f - fi)/(2fs)), fi – fs f fi + fs, i=1,2, …,N
Examples … (continued)
Shaping of phase characteristics i(f), i = 1,2, … ,N, are identically shaped, i.e. –
i+1(f) = i(f-fs) i = 1,2, … ,N-1 equation (8) holds when
f - fi f – fi f - fi
i(f) = h + 0 + m Cos m + n Sin n
2fs m fs n fs
m=1,2,3,4,5, … n=2,4,6, … fi – fs f fi+fs
An example with all coefficients zero, except 2 = 0.3 and h is set to –1
Shaping of phase…. (continued)
Satisfaction of 1st and 2nd requirements -
No perpendicular cutoffs and linear phase characteristics are not required
Overall baseband bandwidth = (N+1)fs
As data rate/channel is 2fs,
Overall data rate = 2N fs
= [2N/(N+1)]. Overall baseband b/w
= [N/(N+1)]. Rmax
Where Rmax is 2 times overall baseband b/w, is the Nyquist rate.
So, for large N, overall data rate approaches Rmax
Satisfaction of 3rd and 4th requirements - Since phase chracteristic (f) of the transmission medium does not enter
into equatios (1) and (2), the received will remain orthogonal for all (f).
In the case of the fourth requirement, let
bki, k = 0, 1, 2, …; i = 1, 2, … ,N, and
cki, k = 0, 1, 2, …; i = 1, 2, … ,N
be two arbitrary distinct sets of m-ary signal digits to be transmitted by N channels.
The distance in signal space between these two received signal sets d = [ [ bk
i ui(t - kT) - cki ui(t - kT) ]2 dt ]½
- i k i k With no ISI and ICI and applying transform domain identity – dideal = [ (bk
i - cki)2 Ai
2(f) H2(f) df ]½
i k - Thus didealis independent of the phase characteristics i(f) and (f).
Receiver structure
FFT based modulation and demodulation
Modulation using IDFT
Create N = 2N information symbols by defining
XN-k = Xk*, k=1, ……. ,N-1
and X0 = Re{X0}, and XN = Im(X0)
Then N-point IDFT yields the real-valued sequence 1 N-1
xn = Xk eJ2nk / N , n = 0,1,2,…N-1
N k=0 where 1/N is simply a scale factor.
The resulting baseband signal is then converted back into serial data and undergoes the addition of the cyclic prefix (which will be explained in the next section). In practice, the signal samples {xn} are passed through a digital-to-analog (D/A) converter at time intervals T/N. Next, the signal is passed through a low-pass filter to remove any unwanted high-frequency noise. The resulting signal closely approximates the frequency division multiplexed signal.
Cyclic prefix and demodulation using DFT Cyclic Prefix:
-acts as a guard space,
-as cyclic convolution is performed with channel impulse response, orthogonality of subcarriers is maintained.
Demodulation using DFT:
Demodulated sequence will be-
Xk = HkXk + k, k = 0,1, …, N-1
where {Xk} is the output of the N-point DFT demodulator, and k is
the additive noise corrupting the signal.
Downsides of OFDM
Cyclic Prefix Overhead Frequency Control Requirement of coded or adaptive OFDM Latency and block based processing Synchronization Peak-to-average power ratio (PAR)
Future research scope
Goals: - Increase capacity, high data rate, minimum bit error rate (BER),
spectral efficiency, minimum power requirements
Problems: - Spectral limitations, channel delay/doppler shifts, limitation in transmission power, real time, PAR
Issues: - coding, diversity, frame overlapping, synchronisation techniques, adaptive estimation, w/f shaping, combined approaches, OFDM application specific DSP architecture AND Any of the combination of above issues to achieve ‘Goals’ in presence of ‘Problems’.