Orthogonal frequency-division multiplexing

Orthogonal frequency-division multiplexing (OFDM) is a method of encoding digital data on multiple carrier frequencies. OFDM has developed into a popular scheme for wideband digital communication, used in applications such as digital television and audio broadcasting, DSL Internet access, wireless networks, powerline networks, and 4G mobile communications.

OFDM is a frequency-division multiplexing (FDM) scheme used as a digital multi-carrier modulation method. A large number of closely spaced orthogonal sub-carrier signals are used to carry data[1] on several parallel data streams or channels. Each sub-carrier is modulated with a conventional modulation scheme (such as quadrature amplitude modulation or phase-shift keying) at a low symbol rate, maintaining total data rates similar to conventional single-carrier modulation schemes in the same bandwidth.

The primary advantage of OFDM over single-carrier schemes is its ability to cope with severe channel conditions (for example, attenuation of high frequencies in a long copper wire, narrowband interference and frequency-selective fading due to multipath) without complex equalization filters. Channel equalization is simplified because OFDM may be viewed as using many slowly modulated narrowband signals rather than one rapidly modulated wideband signal. The low symbol rate makes the use of a guard interval between symbols affordable, making it possible to eliminate intersymbol interference (ISI) and utilize echoes and time-spreading (on analogue TV these are visible as ghosting and blurring, respectively) to achieve a diversity gain, i.e. a signal-to-noise ratio improvement. This mechanism also facilitates the design of single frequency networks (SFNs), where several adjacent transmitters send the same signal simultaneously at the same frequency, as the signals from multiple distant transmitters may be combined constructively, rather than interfering as would typically occur in a traditional single-carrier system.

Example of applications

The following list is a summary of existing OFDM based standards and products. For further details, see the Usage section at the end of the article.

Cable

Wireless

The OFDM based multiple access technology OFDMA is also used in several 4G and pre-4G cellular networks and mobile broadband standards:

Key features

The advantages and disadvantages listed below are further discussed in the Characteristics and principles of operation section below.

Summary of advantages

Summary of disadvantages

Characteristics and principles of operation

Orthogonality

Conceptually, OFDM is a specialized FDM, the additional constraint being that all carrier signals are orthogonal to one another.

In OFDM, the sub-carrier frequencies are chosen so that the sub-carriers are orthogonal to each other, meaning that cross-talk between the sub-channels is eliminated and inter-carrier guard bands are not required. This greatly simplifies the design of both the transmitter and the receiver; unlike conventional FDM, a separate filter for each sub-channel is not required.

The orthogonality requires that the sub-carrier spacing is \scriptstyle\Delta f \,=\, \frac{k}{T_U} Hertz, where TU seconds is the useful symbol duration (the receiver side window size), and k is a positive integer, typically equal to 1. Therefore, with N sub-carriers, the total passband bandwidth will be BN·Δf (Hz).

The orthogonality also allows high spectral efficiency, with a total symbol rate near the Nyquist rate for the equivalent baseband signal (i.e. near half the Nyquist rate for the double-side band physical passband signal). Almost the whole available frequency band can be utilized. OFDM generally has a nearly 'white' spectrum, giving it benign electromagnetic interference properties with respect to other co-channel users.

A simple example: A useful symbol duration TU = 1 ms would require a sub-carrier spacing of \scriptstyle\Delta f \,=\, \frac{1}{1\,\mathrm{ms}} \,=\, 1\,\mathrm{kHz} (or an integer multiple of that) for orthogonality. N = 1,000 sub-carriers would result in a total passband bandwidth of NΔf = 1 MHz. For this symbol time, the required bandwidth in theory according to Nyquist is N=1/2TU = 0.5 MHz (i.e., half of the achieved bandwidth required by our scheme). If a guard interval is applied (see below), Nyquist bandwidth requirement would be even lower. The FFT would result in N = 1,000 samples per symbol. If no guard interval was applied, this would result in a base band complex valued signal with a sample rate of 1 MHz, which would require a baseband bandwidth of 0.5 MHz according to Nyquist. However, the passband RF signal is produced by multiplying the baseband signal with a carrier waveform (i.e., double-sideband quadrature amplitude-modulation) resulting in a passband bandwidth of 1 MHz. A single-side band (SSB) or vestigial sideband (VSB) modulation scheme would achieve almost half that bandwidth for the same symbol rate (i.e., twice as high spectral efficiency for the same symbol alphabet length). It is however more sensitive to multipath interference.

OFDM requires very accurate frequency synchronization between the receiver and the transmitter; with frequency deviation the sub-carriers will no longer be orthogonal, causing inter-carrier interference (ICI) (i.e., cross-talk between the sub-carriers). Frequency offsets are typically caused by mismatched transmitter and receiver oscillators, or by Doppler shift due to movement. While Doppler shift alone may be compensated for by the receiver, the situation is worsened when combined with multipath, as reflections will appear at various frequency offsets, which is much harder to correct. This effect typically worsens as speed increases,[3] and is an important factor limiting the use of OFDM in high-speed vehicles. In order to mitigate ICI in such scenarios, one can shape each sub-carrier in order to minimize the interference resulting in a non-orthogonal subcarriers overlapping.[4] For example, a low-complexity scheme referred to as WCP-OFDM (Weighted Cyclic Prefix Orthogonal Frequency-Division Multiplexing) consists in using short filters at the transmitter output in order to perform a potentially non-rectangular pulse shaping and a near perfect reconstruction using a single-tap per subcarrier equalization.[5] Other ICI suppression techniques usually increase drastically the receiver complexity.[6]

Implementation using the FFT algorithm

The orthogonality allows for efficient modulator and demodulator implementation using the FFT algorithm on the receiver side, and inverse FFT on the sender side. Although the principles and some of the benefits have been known since the 1960s, OFDM is popular for wideband communications today by way of low-cost digital signal processing components that can efficiently calculate the FFT.

The time to compute the inverse-FFT or FFT transform has to take less than the time for each symbol.,[7] which for example for DVB-T (FFT 8k) means the computation has to be done in 896 µs or less.

For an 8192-point FFT this may be approximated to:[7]

\begin{align}
  \mathrm{MIPS}
   &= \frac {\mathrm{computational\ complexity}}{T_\mathrm{symbol}} \times 1.3 \times 10^{-6} \\
   &= \frac{147\;456 \times 2}{896 \times 10^{-6}} \times 1.3 \times 10^{-6} \\
   &= 428
\end{align}[7]

The computational demand approximately scales linearly with FFT size so a double size FFT needs double the amount of time and vice versa.[7] As a comparison an Intel Pentium III CPU at 1.266 GHz is able to calculate a 8 192 point FFT in 576 µs using FFTW.[8] Intel Pentium M at 1.6 GHz does it in 387 µs.[9] Intel Core Duo at 3.0 GHz does it in 96.8 µs.[10]

Guard interval for elimination of intersymbol interference

One key principle of OFDM is that since low symbol rate modulation schemes (i.e., where the symbols are relatively long compared to the channel time characteristics) suffer less from intersymbol interference caused by multipath propagation, it is advantageous to transmit a number of low-rate streams in parallel instead of a single high-rate stream. Since the duration of each symbol is long, it is feasible to insert a guard interval between the OFDM symbols, thus eliminating the intersymbol interference.

The guard interval also eliminates the need for a pulse-shaping filter, and it reduces the sensitivity to time synchronization problems.

A simple example: If one sends a million symbols per second using conventional single-carrier modulation over a wireless channel, then the duration of each symbol would be one microsecond or less. This imposes severe constraints on synchronization and necessitates the removal of multipath interference. If the same million symbols per second are spread among one thousand sub-channels, the duration of each symbol can be longer by a factor of a thousand (i.e., one millisecond) for orthogonality with approximately the same bandwidth. Assume that a guard interval of 1/8 of the symbol length is inserted between each symbol. Intersymbol interference can be avoided if the multipath time-spreading (the time between the reception of the first and the last echo) is shorter than the guard interval (i.e., 125 microseconds). This corresponds to a maximum difference of 37.5 kilometers between the lengths of the paths.

The cyclic prefix, which is transmitted during the guard interval, consists of the end of the OFDM symbol copied into the guard interval, and the guard interval is transmitted followed by the OFDM symbol. The reason that the guard interval consists of a copy of the end of the OFDM symbol is so that the receiver will integrate over an integer number of sinusoid cycles for each of the multipaths when it performs OFDM demodulation with the FFT. In some standards such as Ultrawideband, in the interest of transmitted power, cyclic prefix is skipped and nothing is sent during the guard interval. The receiver will then have to mimic the cyclic prefix functionality by copying the end part of the OFDM symbol and adding it to the beginning portion.

Simplified equalization

The effects of frequency-selective channel conditions, for example fading caused by multipath propagation, can be considered as constant (flat) over an OFDM sub-channel if the sub-channel is sufficiently narrow-banded (i.e., if the number of sub-channels is sufficiently large). This makes frequency domain equalization possible at the receiver, which is far simpler than the time-domain equalization used in conventional single-carrier modulation. In OFDM, the equalizer only has to multiply each detected sub-carrier (each Fourier coefficient) in each OFDM symbol by a constant complex number, or a rarely changed value.

Our example: The OFDM equalization in the above numerical example would require one complex valued multiplication per subcarrier and symbol (i.e., \scriptstyle N \,=\, 1000 complex multiplications per OFDM symbol; i.e., one million multiplications per second, at the receiver). The FFT algorithm requires \scriptstyle N \log_2 N \,=\, 10,000 [this is imprecise: over half of these complex multiplications are trivial, i.e. = to 1 and are not implemented in software or HW]. complex-valued multiplications per OFDM symbol (i.e., 10 million multiplications per second), at both the receiver and transmitter side. This should be compared with the corresponding one million symbols/second single-carrier modulation case mentioned in the example, where the equalization of 125 microseconds time-spreading using a FIR filter would require, in a naive implementation, 125 multiplications per symbol (i.e., 125 million multiplications per second). FFT techniques can be used to reduce the number of multiplications for an FIR filter based time-domain equalizer to a number comparable with OFDM, at the cost of delay between reception and decoding which also becomes comparable with OFDM.

If differential modulation such as DPSK or DQPSK is applied to each sub-carrier, equalization can be completely omitted, since these non-coherent schemes are insensitive to slowly changing amplitude and phase distortion.

In a sense, improvements in FIR equalization using FFTs or partial FFTs leads mathematically closer to OFDM, but the OFDM technique is easier to understand and implement, and the sub-channels can be independently adapted in other ways than varying equalization coefficients, such as switching between different QAM constellation patterns and error-correction schemes to match individual sub-channel noise and interference characteristics.

Some of the sub-carriers in some of the OFDM symbols may carry pilot signals for measurement of the channel conditions[11][12] (i.e., the equalizer gain and phase shift for each sub-carrier). Pilot signals and training symbols (preambles) may also be used for time synchronization (to avoid intersymbol interference, ISI) and frequency synchronization (to avoid inter-carrier interference, ICI, caused by Doppler shift).

OFDM was initially used for wired and stationary wireless communications. However, with an increasing number of applications operating in highly mobile environments, the effect of dispersive fading caused by a combination of multi-path propagation and doppler shift is more significant. Over the last decade, research has been done on how to equalize OFDM transmission over doubly selective channels.[13][14][15]

Channel coding and interleaving

OFDM is invariably used in conjunction with channel coding (forward error correction), and almost always uses frequency and/or time interleaving.

Frequency (subcarrier) interleaving increases resistance to frequency-selective channel conditions such as fading. For example, when a part of the channel bandwidth fades, frequency interleaving ensures that the bit errors that would result from those subcarriers in the faded part of the bandwidth are spread out in the bit-stream rather than being concentrated. Similarly, time interleaving ensures that bits that are originally close together in the bit-stream are transmitted far apart in time, thus mitigating against severe fading as would happen when travelling at high speed.

However, time interleaving is of little benefit in slowly fading channels, such as for stationary reception, and frequency interleaving offers little to no benefit for narrowband channels that suffer from flat-fading (where the whole channel bandwidth fades at the same time).

The reason why interleaving is used on OFDM is to attempt to spread the errors out in the bit-stream that is presented to the error correction decoder, because when such decoders are presented with a high concentration of errors the decoder is unable to correct all the bit errors, and a burst of uncorrected errors occurs. A similar design of audio data encoding makes compact disc (CD) playback robust.

A classical type of error correction coding used with OFDM-based systems is convolutional coding, often concatenated with Reed-Solomon coding. Usually, additional interleaving (on top of the time and frequency interleaving mentioned above) in between the two layers of coding is implemented. The choice for Reed-Solomon coding as the outer error correction code is based on the observation that the Viterbi decoder used for inner convolutional decoding produces short error bursts when there is a high concentration of errors, and Reed-Solomon codes are inherently well-suited to correcting bursts of errors.

Newer systems, however, usually now adopt near-optimal types of error correction codes that use the turbo decoding principle, where the decoder iterates towards the desired solution. Examples of such error correction coding types include turbo codes and LDPC codes, which perform close to the Shannon limit for the Additive White Gaussian Noise (AWGN) channel. Some systems that have implemented these codes have concatenated them with either Reed-Solomon (for example on the MediaFLO system) or BCH codes (on the DVB-S2 system) to improve upon an error floor inherent to these codes at high signal-to-noise ratios.[16]

Adaptive transmission

The resilience to severe channel conditions can be further enhanced if information about the channel is sent over a return-channel. Based on this feedback information, adaptive modulation, channel coding and power allocation may be applied across all sub-carriers, or individually to each sub-carrier. In the latter case, if a particular range of frequencies suffers from interference or attenuation, the carriers within that range can be disabled or made to run slower by applying more robust modulation or error coding to those sub-carriers.

The term discrete multitone modulation (DMT) denotes OFDM based communication systems that adapt the transmission to the channel conditions individually for each sub-carrier, by means of so-called bit-loading. Examples are ADSL and VDSL.

The upstream and downstream speeds can be varied by allocating either more or fewer carriers for each purpose. Some forms of rate-adaptive DSL use this feature in real time, so that the bitrate is adapted to the co-channel interference and bandwidth is allocated to whichever subscriber needs it most.

OFDM extended with multiple access

OFDM in its primary form is considered as a digital modulation technique, and not a multi-user channel access method, since it is utilized for transferring one bit stream over one communication channel using one sequence of OFDM symbols. However, OFDM can be combined with multiple access using time, frequency or coding separation of the users.

In orthogonal frequency-division multiple access (OFDMA), frequency-division multiple access is achieved by assigning different OFDM sub-channels to different users. OFDMA supports differentiated quality of service by assigning different number of sub-carriers to different users in a similar fashion as in CDMA, and thus complex packet scheduling or Media Access Control schemes can be avoided. OFDMA is used in:

OFDMA is also a candidate access method for the IEEE 802.22 Wireless Regional Area Networks (WRAN). The project aims at designing the first cognitive radio based standard operating in the VHF-low UHF spectrum (TV spectrum).

In Multi-carrier code division multiple access (MC-CDMA), also known as OFDM-CDMA, OFDM is combined with CDMA spread spectrum communication for coding separation of the users. Co-channel interference can be mitigated, meaning that manual fixed channel allocation (FCA) frequency planning is simplified, or complex dynamic channel allocation (DCA) schemes are avoided.

Space diversity

In OFDM based wide area broadcasting, receivers can benefit from receiving signals from several spatially dispersed transmitters simultaneously, since transmitters will only destructively interfere with each other on a limited number of sub-carriers, whereas in general they will actually reinforce coverage over a wide area. This is very beneficial in many countries, as it permits the operation of national single-frequency networks (SFN), where many transmitters send the same signal simultaneously over the same channel frequency. SFNs utilise the available spectrum more effectively than conventional multi-frequency broadcast networks (MFN), where program content is replicated on different carrier frequencies. SFNs also result in a diversity gain in receivers situated midway between the transmitters. The coverage area is increased and the outage probability decreased in comparison to an MFN, due to increased received signal strength averaged over all sub-carriers.

Although the guard interval only contains redundant data, which means that it reduces the capacity, some OFDM-based systems, such as some of the broadcasting systems, deliberately use a long guard interval in order to allow the transmitters to be spaced farther apart in an SFN, and longer guard intervals allow larger SFN cell-sizes. A rule of thumb for the maximum distance between transmitters in an SFN is equal to the distance a signal travels during the guard interval — for instance, a guard interval of 200 microseconds would allow transmitters to be spaced 60 km apart.

A single frequency network is a form of transmitter macrodiversity. The concept can be further utilized in dynamic single-frequency networks (DSFN), where the SFN grouping is changed from timeslot to timeslot.

OFDM may be combined with other forms of space diversity, for example antenna arrays and MIMO channels. This is done in the IEEE 802.11 Wireless LAN standards.

Linear transmitter power amplifier

An OFDM signal exhibits a high peak-to-average power ratio (PAPR) because the independent phases of the sub-carriers mean that they will often combine constructively. Handling this high PAPR requires:

Any non-linearity in the signal chain will cause intermodulation distortion that

The linearity requirement is demanding, especially for transmitter RF output circuitry where amplifiers are often designed to be non-linear in order to minimise power consumption. In practical OFDM systems a small amount of peak clipping is allowed to limit the PAPR in a judicious trade-off against the above consequences. However, the transmitter output filter which is required to reduce out-of-band spurs to legal levels has the effect of restoring peak levels that were clipped, so clipping is not an effective way to reduce PAPR.

Although the spectral efficiency of OFDM is attractive for both terrestrial and space communications, the high PAPR requirements have so far limited OFDM applications to terrestrial systems.

The crest factor CF (in dB) for an OFDM system with n uncorrelated sub-carriers is[17]

   CF = 10 log ( n ) + CFc ...

where CFc is the crest factor (in dB) for each sub-carrier. (CFc is 3.01 dB for the sine waves used for BPSK and QPSK modulation).

For example, the DVB-T signal in 2K mode is composed of 1705 sub-carriers that are each QPSK-modulated, giving a crest factor of 35.32 dB.[17]

Many crest factor reduction techniques have been developed.

The dynamic range required for an FM receiver is 120 dB while DAB only require about 90 dB.[18] As a comparison, each extra bit per sample increases the dynamic range with 6 dB.

Efficiency comparison between single carrier and multicarrier

The performance of any communication system can be measured in terms of its power efficiency and bandwidth efficiency. The power efficiency describes the ability of communication system to preserve bit error rate (BER) of the transmitted signal at low power levels. Bandwidth efficiency reflects how efficiently the allocated bandwidth is utilized and is defined as the throughput data rate per Hertz in a given bandwidth. If the large number of subcarriers are used, the bandwidth efficiency of multicarrier system such as OFDM with using optical fiber channel is defined as[19]

Factor 2 is because of two polarization states in the fiber.

where R_{s} is the symbol rate in giga symbol per second (Gsps), and B_{OFDM} is the bandwidth of OFDM signal.

There is saving of bandwidth by using Multicarrier modulation with orthogonal frequency division multiplexing . So the bandwidth for multicarrier system is less in comparison with single carrier system and hence bandwidth efficiency of multicarrier system is larger than single carrier system.

S.No. Transmission Type M in M-QAM No. of Subcarriers Bit rate Fiber length Power at the receiver (at BER of 10−9) Bandwidth efficiency
1. single carrier 64 1 10 Gbit/s 20 km -37.3 dBm 6.0000
2. multicarrier 64 128 10 Gbit/s 20 km -36.3 dBm 10.6022

There is only 1 dBm increase in receiver power, but we get 76.7% improvement in bandwidth efficiency with using multicarrier transmission technique.

Idealized system model

This section describes a simple idealized OFDM system model suitable for a time-invariant AWGN channel.

Transmitter

An OFDM carrier signal is the sum of a number of orthogonal sub-carriers, with baseband data on each sub-carrier being independently modulated commonly using some type of quadrature amplitude modulation (QAM) or phase-shift keying (PSK). This composite baseband signal is typically used to modulate a main RF carrier.

\scriptstyle s[n] is a serial stream of binary digits. By inverse multiplexing, these are first demultiplexed into \scriptstyle N parallel streams, and each one mapped to a (possibly complex) symbol stream using some modulation constellation (QAM, PSK, etc.). Note that the constellations may be different, so some streams may carry a higher bit-rate than others.

An inverse FFT is computed on each set of symbols, giving a set of complex time-domain samples. These samples are then quadrature-mixed to passband in the standard way. The real and imaginary components are first converted to the analogue domain using digital-to-analogue converters (DACs); the analogue signals are then used to modulate cosine and sine waves at the carrier frequency, \scriptstyle f_c, respectively. These signals are then summed to give the transmission signal, \scriptstyle s(t).

Receiver

The receiver picks up the signal \scriptstyle r(t), which is then quadrature-mixed down to baseband using cosine and sine waves at the carrier frequency. This also creates signals centered on \scriptstyle 2 f_c, so low-pass filters are used to reject these. The baseband signals are then sampled and digitised using analog-to-digital converters (ADCs), and a forward FFT is used to convert back to the frequency domain.

This returns \scriptstyle N parallel streams, each of which is converted to a binary stream using an appropriate symbol detector. These streams are then re-combined into a serial stream, \scriptstyle {\hat s}[n], which is an estimate of the original binary stream at the transmitter.

Mathematical description

If \scriptstyle N sub-carriers are used, and each sub-carrier is modulated using \scriptstyle M alternative symbols, the OFDM symbol alphabet consists of \scriptstyle M^N combined symbols.

The low-pass equivalent OFDM signal is expressed as:


\ \nu(t)=\sum_{k=0}^{N-1}X_k e^{j2\pi kt/T}, \quad 0\le t<T,

where \scriptstyle\{X_k\} are the data symbols, \scriptstyle N is the number of sub-carriers, and \scriptstyle T is the OFDM symbol time. The sub-carrier spacing of \scriptstyle \frac{1}{T} makes them orthogonal over each symbol period; this property is expressed as:


\begin{align}
 &\frac{1}{T}\int_0^{T}\left(e^{j2\pi k_1t/T}\right)^*
\left(e^{j2\pi k_2t/T}\right)dt \\
 = &\frac{1}{T}\int_0^{T}e^{j2\pi (k_2-k_1)t/T}dt = \delta_{k_1k_2}
\end{align}

where \scriptstyle (\cdot)^* denotes the complex conjugate operator and \scriptstyle\delta\, is the Kronecker delta.

To avoid intersymbol interference in multipath fading channels, a guard interval of length \scriptstyle T_\mathrm{g} is inserted prior to the OFDM block. During this interval, a cyclic prefix is transmitted such that the signal in the interval \scriptstyle -T_\mathrm{g} \,\le\, t \,<\, 0 equals the signal in the interval \scriptstyle (T-T_\mathrm{g}) \,\le\, t \,<\, T. The OFDM signal with cyclic prefix is thus:

\ \nu(t)=\sum_{k=0}^{N-1}X_ke^{j2\pi kt/T}, \quad -T_\mathrm{g}\le t < T

The low-pass signal above can be either real or complex-valued. Real-valued low-pass equivalent signals are typically transmitted at baseband—wireline applications such as DSL use this approach. For wireless applications, the low-pass signal is typically complex-valued; in which case, the transmitted signal is up-converted to a carrier frequency \scriptstyle f_c. In general, the transmitted signal can be represented as:


\begin{align}
s(t) & =  \Re\left\{\nu(t) e^{j2\pi f_c t}\right\} \\
     & = \sum_{k=0}^{N-1}|X_k|\cos\left(2\pi [f_c + k/T]t + \arg[X_k]\right)
\end{align}

Usage

OFDM is used in:

OFDM system comparison table

Key features of some common OFDM based systems are presented in the following table.

Standard name DAB Eureka 147 DVB-T DVB-H DMB-T/H DVB-T2 IEEE 802.11a
Ratified year 1995 1997 2004 2006 2007 1999
Frequency range of
today's equipment
174–240 MHz 1,452–1,492 GHz 470–862 MHz 174–230 MHz 470–862 MHz 470–862 MHz 4,915–6,100 GHz
Channel spacing, B
[MHz]
1.712 6, 7, 8 5, 6, 7, 8 8 1.7, 5, 6, 7, 8, 10 20
FFT size (k=1,024) Mode I: 2k
Mode II: 512
Mode III: 256
Mode IV: 1k
2k, 8k 2k, 4k, 8k 1 (single-carrier)
4k (multi-carrier)
1k, 2k, 4k, 8k, 16k, 32k 64
Number of non-silent sub-carriers, N Mode I: 1,536
Mode II: 384
Mode III: 192
Mode IV: 768
2K mode: 1,705
8K mode: 6,817
1,705, 3,409, 6,817 1 (single-carrier)
3,780 (multi-carrier)
853-27,841 (1K normal to 32K extended carrier mode) 52
Sub-carrier modulation scheme π4-DQPSK QPSK,[21] 16QAM or 64QAM QPSK,[21] 16QAM or 64QAM 4QAM,[21] 4QAM-NR,[22]
16QAM, 32QAM and 64QAM.
QPSK, 16QAM, 64QAM, 256QAM BPSK, QPSK,[21] 16QAM or 64QAM
Useful symbol length, TU
(μs)
Mode I: 1,000
Mode II: 250
Mode III: 125
Mode IV: 500
2K mode: 224
8K mode: 896
224, 448, 896 500 (multi-carrier) 112-3,584 (1K to 32K mode on 8 MHz channel) 3.2
Additional guard interval, TG
(fraction of TU)
24.6% (all modes) 14, 18, 116, 132 14, 18, 116, 132 14, 16, 19 1/128, 1/32, 1/16, 19/256, 1/8, 19/128, 1/4.

(For 32k mode maximum 1/8)

14
Sub-carrier spacing
\scriptstyle \Delta f \,=\, \frac{1}{T_U} \,\approx\, \frac{B}{N}
(Hz)
Mode I: 1,000
Mode II: 4,000
Mode III: 8,000
Mode IV: 2,000
2K mode: 4,464
8K mode: 1,116
4,464, 2,232, 1,116 8 M (single-carrier)
2,000 (multi-carrier)
279-8,929 (32K down to 1K mode) 312.5K
Net bit rate, R
(Mbit/s)
0.576–1.152 4.98–31.67
(typically 24.13)
3.7–23.8 4.81–32.49 Typically 35.4 6–54
Link spectral efficiency R/B
(bit/s/Hz)
0.34–0.67 0.62–4.0 (Typ 3.0) 0.62–4.0 0.60–4.1 0.87-6.65 0.30–2.7
Inner FEC Conv coding with

Equal error protection code rates
14, 38, 49, 12, 47, 23, 34, 45
Unequal error protection with av. code rates of
~0.34, 0.41, 0.50, 0.60, and 0.75

Conv. coding with code rates

12, 23, 34, 56, or 78

Conv. coding with code rates

12, 23, 34, 56, or 78

LDPC with code rates

0.4, 0.6 or 0.8

LDPC 1/2, 3/5, 2/3, 3/4, 4/5, 5/6 Conv. coding with code rates

12, 23, or 34

Outer FEC (if any) Optional RS (120, 110, t = 5) RS (204, 188, t=8) RS (204, 188, t=8) + MPE-FEC BCH code (762, 752) BCH code
Maximum travelling speed
(km/h)
200–600 53–185
depends on transmission frequency
Time interleaving depth
(ms)
384 0.6–3.5 0.6–3.5 200–500 up to 250 (500 with extension frame)
Adaptive transmission
(if any)
None None None None
Multiple access method
(if any)
None None None None
Typical source coding 192 kbit/s
MPEG2 Audio
layer 2
2–18 Mbit/s
Standard - HDTV
H.264 or MPEG2
H.264 Not defined
(Video: MPEG-2, H.264 and/or AVS
Audio: MP2 or AC-3)
H.264 or MPEG2
(Audio: AAC HE, Dolby Digital AC-3 (A52), MPEG-2 AL 2.)

ADSL

OFDM is used in ADSL connections that follow the ANSI T1.413 and G.dmt (ITU G.992.1) standards, where it is called discrete multitone modulation (DMT). DSL achieves high-speed data connections on existing copper wires. OFDM is also used in the successor standards ADSL2, ADSL2+, VDSL, VDSL2, and G.fast. ADSL2 uses variable sub-carrier modulation, ranging from BPSK to 32768QAM (in ADSL terminology this is referred to as bit-loading, or bit per tone, 1 to 15 bits per sub-carrier).

Long copper wires suffer from attenuation at high frequencies. The fact that OFDM can cope with this frequency selective attenuation and with narrow-band interference are the main reasons it is frequently used in applications such as ADSL modems. However, DSL cannot be used on every copper pair; interference may become significant if more than 25% of phone lines coming into a central office are used for DSL.

Powerline Technology

OFDM is used by many powerline devices to extend digital connections through power wiring. Adaptive modulation is particularly important with such a noisy channel as electrical wiring. Some medium speed smart metering modems, "Prime" and "G3" use OFDM at modest frequencies (30–100 kHz)with modest numbers of channels (several hundred) in order to overcome the intersymbol interference in the power line environment.[23] The IEEE 1901 standards include two incompatible physical layers that both use OFDM.[24] The ITU-T G.hn standard, which provides high-speed local area networking over existing home wiring (power lines, phone lines and coaxial cables) is based on a PHY layer that specifies OFDM with adaptive modulation and a Low-Density Parity-Check (LDPC) FEC code.[20]

Wireless local area networks (LAN) and metropolitan area networks (MAN)

OFDM is extensively used in wireless LAN and MAN applications, including IEEE 802.11a/g/n and WiMAX.

IEEE 802.11a/g/n, operating in the 2.4 and 5 GHz bands, specifies per-stream airside data rates ranging from 6 to 54 Mbit/s. If both devices can utilize "HT mode" (added with 802.11n), the top 20 MHz per-stream rate is increased to 72.2 Mbit/s, with the option of data rates between 13.5 and 150 Mbit/s using a 40 MHz channel. Four different modulation schemes are used: BPSK, QPSK, 16-QAM, and 64-QAM, along with a set of error correcting rates (1/2–5/6). The multitude of choices allows the system to adapt the optimum data rate for the current signal conditions.

Wireless personal area networks (PAN)

OFDM is also now being used in the WiMedia/Ecma-368 standard for high-speed wireless personal area networks in the 3.1–10.6 GHz ultrawideband spectrum (see MultiBand-OFDM).

Terrestrial digital radio and television broadcasting

Much of Europe and Asia has adopted OFDM for terrestrial broadcasting of digital television (DVB-T, DVB-H and T-DMB) and radio (EUREKA 147 DAB, Digital Radio Mondiale, HD Radio and T-DMB).

DVB-T

By Directive of the European Commission, all television services transmitted to viewers in the European Community must use a transmission system that has been standardized by a recognized European standardization body,[25] and such a standard has been developed and codified by the DVB Project, Digital Video Broadcasting (DVB); Framing structure, channel coding and modulation for digital terrestrial television.[26] Customarily referred to as DVB-T, the standard calls for the exclusive use of COFDM for modulation. DVB-T is now widely used in Europe and elsewhere for terrestrial digital TV.

SDARS

The ground segments of the Digital Audio Radio Service (SDARS) systems used by XM Satellite Radio and Sirius Satellite Radio are transmitted using Coded OFDM (COFDM).[27] The word "coded" comes from the use of forward error correction (FEC).[1]

COFDM vs VSB

The question of the relative technical merits of COFDM versus 8VSB for terrestrial digital television has been a subject of some controversy, especially between European and North American technologists and regulators. The United States has rejected several proposals to adopt the COFDM based DVB-T system for its digital television services, and has instead opted for 8VSB (vestigial sideband modulation) operation.

One of the major benefits provided by COFDM is in rendering radio broadcasts relatively immune to multipath distortion and signal fading due to atmospheric conditions or passing aircraft. Proponents of COFDM argue it resists multipath far better than 8VSB. Early 8VSB DTV (digital television) receivers often had difficulty receiving a signal. Also, COFDM allows single-frequency networks, which is not possible with 8VSB.

However, newer 8VSB receivers are far better at dealing with multipath, hence the difference in performance may diminish with advances in equalizer design.

Digital radio

COFDM is also used for other radio standards, for Digital Audio Broadcasting (DAB), the standard for digital audio broadcasting at VHF frequencies, for Digital Radio Mondiale (DRM), the standard for digital broadcasting at shortwave and medium wave frequencies (below 30 MHz) and for DRM+ a more recently introduced standard for digital audio broadcasting at VHF frequencies. (30 to 174 MHz)

The USA again uses an alternate standard, a proprietary system developed by iBiquity dubbed HD Radio. However, it uses COFDM as the underlying broadcast technology to add digital audio to AM (medium wave) and FM broadcasts.

Both Digital Radio Mondiale and HD Radio are classified as in-band on-channel systems, unlike Eureka 147 (DAB: Digital Audio Broadcasting) which uses separate VHF or UHF frequency bands instead.

BST-OFDM used in ISDB

The band-segmented transmission orthogonal frequency division multiplexing (BST-OFDM) system proposed for Japan (in the ISDB-T, ISDB-TSB, and ISDB-C broadcasting systems) improves upon COFDM by exploiting the fact that some OFDM carriers may be modulated differently from others within the same multiplex. Some forms of COFDM already offer this kind of hierarchical modulation, though BST-OFDM is intended to make it more flexible. The 6 MHz television channel may therefore be "segmented", with different segments being modulated differently and used for different services.

It is possible, for example, to send an audio service on a segment that includes a segment composed of a number of carriers, a data service on another segment and a television service on yet another segment—all within the same 6 MHz television channel. Furthermore, these may be modulated with different parameters so that, for example, the audio and data services could be optimized for mobile reception, while the television service is optimized for stationary reception in a high-multipath environment.

Ultra-wideband

Ultra-wideband (UWB) wireless personal area network technology may also utilise OFDM, such as in Multiband OFDM (MB-OFDM). This UWB specification is advocated by the WiMedia Alliance (formerly by both the Multiband OFDM Alliance [MBOA] and the WiMedia Alliance, but the two have now merged), and is one of the competing UWB radio interfaces.

FLASH-OFDM

Fast low-latency access with seamless handoff orthogonal frequency division multiplexing (Flash-OFDM), also referred to as F-OFDM, was based on OFDM and also specified higher protocol layers. It was developed by Flarion, and purchased by Qualcomm in January 2006.[28][29] Flash-OFDM was marketed as a packet-switched cellular bearer, to compete with GSM and 3G networks. As an example, 450 MHz frequency bands previously used by NMT-450 and C-Net C450 (both 1G analogue networks, now mostly decommissioned) in Europe are being licensed to Flash-OFDM operators.

In Finland, the license holder Digita began deployment of a nationwide "@450" wireless network in parts of the country since April 2007. It was purchased by Datame in 2011.[30] In February 2012 Datame announced they would upgrade the 450 MHz network to competing CDMA2000 technology.[31]

Slovak Telekom in Slovakia offers Flash-OFDM connections[32] with a maximum downstream speed of 5.3 Mbit/s, and a maximum upstream speed of 1.8 Mbit/s, with a coverage of over 70 percent of Slovak population. The Flash-OFDM network is due to be switched off in the majority of Slovakia from 30 September 2015.[33]

T-Mobile Germany uses Flash-OFDM to backhaul Wi-Fi HotSpots on the Deutsche Bahn's ICE high speed trains.

American wireless carrier Nextel Communications field tested wireless broadband network technologies including Flash-OFDM in 2005.[34] Sprint purchased the carrier in 2006 and decided to deploy the mobile version of WiMAX, which is based on Scalable Orthogonal Frequency Division Multiple Access (SOFDMA) technology.[35]

Citizens Telephone Cooperative launched a mobile broadband service based on Flash-OFDM technology to subscribers in parts of Virginia in March 2006. The maximum speed available was 1.5 Mbit/s.[36] The service was discontinued on April 30, 2009.[37]

Digiweb Ltd. launched a mobile broadband network using Flash-OFDM technology at 872 MHz in July 2007 in Ireland and Digiweb also owns a national 872 MHz license in Norway. Voice handsets are not yet available as of November 2007. The deployment is live in a small area north of Dublin only.

Butler Networks operates a Flash-OFDM network in Denmark at 872 MHz.

In Netherlands, KPN-telecom will start a pilot around July 2007.

History

See also

References

  1. 1 2 webe.org - 2GHz BAS Relocation Tech-Fair, COFDM Technology Basics. 2007-03-02
  2. Ben-Tovim, Erez (February 2014). "ITU G.hn - Broadband Home Networking". In Berger, Lars T.; Schwager, Andreas; Pagani, Pascal; Schneider, Daniel M. MIMO Power Line Communications. Devices, Circuits, and Systems. CRC Press. ISBN 9781466557529.
  3. Robertson, P.; Kaiser, S. "The effects of Doppler spreads in OFDM(A) mobile radio systems", Vehicular Technology Conference, 1999. VTC 1999 - Fall. IEEE VTS. Link
  4. Haas, R.; Belfiore, J.C. (1997). "A Time-Frequency Well-localized Pulse for Multiple Carrier Transmission". Wireless Personal Communications 5 (1): 1–18. doi:10.1023/A:1008859809455..
  5. Roque, D.; Siclet, C. (2013). "Performances of Weighted Cyclic Prefix OFDM with Low-Complexity Equalization". IEEE Communications Letters 17 (3): 439–442. doi:10.1109/LCOMM.2013.011513.121997..
  6. Jeon, W.G.; Chang, K.H.; Cho, Y.S. (1999). "An equalization technique for orthogonal frequency-division multiplexing systems in time-variant multipath channels". IEEE Transactions on Communications 47 (1): 27–32. doi:10.1109/26.747810..
  7. 1 2 3 4 sharif.ir - The suitability of OFDM as a modulation technique for wireless telecommunications, with a CDMA comparison., October 1997
  8. fftw.org - 1.266 GHz Pentium 3, 2006-06-20
  9. fftw.org - 1.6 GHz Pentium M (Banias), GNU compilers, 2006-06-20
  10. fftw.org - 3.0 GHz Intel Core Duo, Intel compilers, 32-bit mode, 2006-10-09
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  12. Hoeher, P. Kaiser, S. Robertson, P. "Two-dimensional pilot-symbol-aided channel estimation by Wienerfiltering". IEEE International Conference on Acoustics, Speech, and Signal Processing, ICASSP-97, 1997. Link
  13. "Zemen, T.; Mecklenbrauker, C.F., Time-Variant Channel Estimation Using Discrete Prolate Spheroidal Sequences. Signal Processing, IEEE Transactions on, vol.53, no.9, pp. 3597- 3607, Sept. 2005 doi:10.1109/TSP.2005.853104" Link
  14. "Zijian Tang; Cannizzaro, R.C.; Leus, G.; Banelli, P., Pilot-Assisted Time-Varying Channel Estimation for OFDM Systems, Signal Processing, IEEE Transactions on, vol.55, no.5, pp.2226-2238, May 2007 doi:10.1109/TSP.2007.893198" Link
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  17. 1 2 Bernhard Kaehs. "The Crest Factor in DVB-T (OFDM) Transmitter Systems and its Influence on the Dimensioning of Power Components"
  18. Digital Audio Broadcasting: Principles and Applications of DAB, DAB + and DMB. 2009. p. 333. Retrieved 2013-07-04. (3rd edition 2009)
  19. William Shieh, Ivan Djordjevic. (2010). "OFDM for Optical Communications". 525 B Street, Suite 1900, San Diego, California 92101-4495, USA: Academic Press.
  20. 1 2 Berger, Lars T.; Schwager, Andreas; Pagani, Pascal; Schneider, Daniel M., eds. (February 2014). MIMO Power Line Communications: Narrow and Broadband Standards, EMC, and Advanced Processing. Devices, Circuits, and Systems. CRC Press. ISBN 9781466557529.
  21. 1 2 3 4 4QAM is equivalent to QPSK
  22. NR refers to Nordstrom-Robinson code
  23. Hoch, Martin; Comparison of PLC G3 and Prime, 2011 IEEE Symposium on Powerline Communication and its Applications
  24. Stefano Galli et al. (July 2008). "Recent Developments in the Standardization of Power Line Communications within the IEEE". IEEE Communications Magazine 46 (7): 64–71. doi:10.1109/MCOM.2008.4557044. An overview of P1901 PHY/MAC proposal.
  25. DIRECTIVE 95/47/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL on the use of standards for the transmission of television signals
  26. ETSI Standard: EN 300 744 V1.5.1 (2004-11).
  27. http://www.commsdesign.com/article/printableArticle.jhtml?articleID=12805708 Agere gets Sirius about satellite radio design
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  29. "Qualcomm Completes Acquisition Of WiMAX Competitor". Network Computing. January 19, 2006. Retrieved July 23, 2011.
  30. "Briefly in English". @450-Network web site. Datame. Retrieved July 23, 2011.
  31. Aleksi Kolehmainen (February 8, 2012). "@450 siirtyy cdma2000-tekniikkaan - jopa puhelut mahdollisia". Tietoviikko (in Finnish).
  32. "Mapy pokrytia". Slovak Telekom web site (in Slovak). Retrieved May 30, 2012.
  33. "Slovak Telekom shut down Flash-OFDM". telecompaper. September 30, 2015.
  34. "Nextel Flash-OFDM: The Best Network You May Never Use". PC Magazine. March 2, 2005. Retrieved July 23, 2011.
  35. Sascha Segan (August 8, 2006). "Sprint Nextel Goes To The WiMax". PC Magazine. Retrieved July 23, 2011.
  36. "Citizens Offers First "Truly Mobile" Wireless Internet in Christiansburg and other parts of the New River Valley" (PDF). News release (Citizens Wireless). March 28, 2006. Retrieved July 23, 2011.
  37. "Thank you for supporting Citizens Mobile Broadband". Citizens Wireless. 2009. Retrieved July 23, 2011.
  38. Chang, R. W. (1966). "Synthesis of band-limited orthogonal signals for multi-channel data transmission". Bell System Technical Journal 45 (10): 1775–1796. doi:10.1002/j.1538-7305.1966.tb02435.x.
  39. US 3488445
  40. S.Weinstein and P. Ebert, Data transmission by frequency-division multiplexing using the discrete Fourier transform, IEEE Transactions on Communication Technology, vol. 19, no. 5, pp. 628–634, October 1971.
  41. http://www.wipo.int/pctdb/en/wo.jsp?WO=1990/04893
  42. Nortel 3G World Congress Press Release

Further reading

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